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1 7 Polynomial Equations and Factoring 7.1 Adding and Subtracting Polynomials 7.2 Multiplying Polynomials 7.3 Special Products of Polynomials 7.4 Solving Polynomial Equations in Factored Form 7.5 Factoring x 2 + bx + c 7.6 Factoring ax 2 + bx + c 7.7 Factoring Special Products 7.8 Factoring Polynomials Completely SEE the Big Idea Height of a Falling Object (p. 400) Game Reserve (p. 394) Photo Cropping (p. 390) Framing a Photo (p. 370) Gateway Arch (p. 382)

8(y 3) + 2y = 8(y) ( 8)(3) + 2y Distributive Property = 8y + 24 + 2y Multiply. = 8y + 2y + 24 Commutative Property of Addition = ( 8 + 2)y + 24 Distributive Property = 6y + 24 Simplify.

2 Maintaining Mathematical Proficiency Simplifying Algebraic Expressions Example 1 Simplify 6x + 5 3x 4. 6x + 5 3x 4 = 6x 3x Commutative Property of Addition = (6 3)x Distributive Property = 3x + 1 Simplify. Example 2 Simplify 8( y 3) + 2y. 8(y 3) + 2y = 8(y) ( 8)(3) + 2y Distributive Property = 8y y Multiply. = 8y + 2y + 24 Commutative Property of Addition = ( 8 + 2)y + 24 Distributive Property = 6y + 24 Simplify. Simplify the expression. 1. 3x 7 + 2x 2. 4r + 6 9r t + 3 t 4 + 8t 4. 3(s 1) m 7(3 m) 6. 4(h + 6) (h 2) Finding the Greatest Common Factor Example 3 Find the greatest common factor (GCF) of 42 and 70. To find the GCF of two numbers, first write the prime factorization of each number. Then find the product of the common prime factors. 42 = = The GCF of 42 and 70 is 2 7 = 14. Find the greatest common factor , , , , , , ABSTRACT REASONING Is it possible for two integers to have no common factors? Explain your reasoning. Dynamic Solutions available at BigIdeasMath.com 355

3 Mathematical Practices Using Models Core Concept Using Algebra Tiles Mathematically profi cient students consider concrete models when solving a mathematics problem. When solving a problem, it can be helpful to use a model. For instance, you can use algebra tiles to model algebraic expressions and operations with algebraic expressions. 1 1 x x x 2 x 2 Writing Expressions Modeled by Algebra Tiles Write the algebraic expression modeled by the algebra tiles. a. b. c. a. The algebraic expression is x 2. b. The algebraic expression is 3x + 4. c. The algebraic expression is x 2 x + 2. Monitoring Progress Write the algebraic expression modeled by the algebra tiles Chapter 7 Polynomial Equations and Factoring

4 7.1 Adding and Subtracting Polynomials Essential Question How can you add and subtract polynomials? Adding Polynomials Work with a partner. Write the expression modeled by the algebra tiles in each step. Step 1 + (3x + 2) + (x 5) Step 2 Step 3 Step 4 Subtracting Polynomials Work with a partner. Write the expression modeled by the algebra tiles in each step. Step 1 (x 2 + 2x + 2) (x 1) Step 2 + Step 3 Step 4 REASONING ABSTRACTLY To be proficient in math, you need to represent a given situation using symbols. Step 5 Communicate Your Answer 3. How can you add and subtract polynomials? 4. Use your methods in Question 3 to find each sum or difference. a. (x 2 + 2x 1) + (2x 2 2x + 1) b. (4x + 3) + (x 2) c. (x 2 + 2) (3x 2 + 2x + 5) d. (2x 3x) (x 2 2x + 4) Section 7.1 Adding and Subtracting Polynomials 357

5 7.1 Lesson What You Will Learn Core Vocabulary monomial, p. 358 degree of a monomial, p. 358 polynomial, p. 359 binomial, p. 359 trinomial, p. 359 degree of a polynomial, p. 359 standard form, p. 359 leading coefficient, p. 359 closed, p. 360 Find the degrees of monomials. Classify polynomials. Add and subtract polynomials. Solve real-life problems. Finding the Degrees of Monomials A monomial is a number, a variable, or the product of a number and one or more variables with whole number exponents. The degree of a monomial is the sum of the exponents of the variables in the monomial. The degree of a nonzero constant term is 0. The constant 0 does not have a degree. Monomial Degree Not a monomial Reason x A sum is not a monomial. 3x 1 2 n A monomial cannot have a variable in the denominator. 1 2 ab = 3 4 a A monomial cannot have a variable exponent. 1.8m 5 5 x 1 The variable must have a whole number exponent. Find the degree of each monomial. Finding the Degrees of Monomials 1 a. 5x 2 b. 2 xy3 c. 8x 3 y 3 d. 3 a. The exponent of x is 2. So, the degree of the monomial is 2. b. The exponent of x is 1, and the exponent of y is 3. So, the degree of the monomial is 1 + 3, or 4. c. The exponent of x is 3, and the exponent of y is 3. So, the degree of the monomial is 3 + 3, or 6. d. You can rewrite 3 as 3x 0. So, the degree of the monomial is 0. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Find the degree of the monomial. 1. 3x c 3 d y Chapter 7 Polynomial Equations and Factoring

6 Classifying Polynomials Core Concept Polynomials A polynomial is a monomial or a sum of monomials. Each monomial is called a term of the polynomial. A polynomial with two terms is a binomial. A polynomial with three terms is a trinomial. Binomial Trinomial 5x + 2 x 2 + 5x + 2 The degree of a polynomial is the greatest degree of its terms. A polynomial in one variable is in standard form when the exponents of the terms decrease from left to right. When you write a polynomial in standard form, the coefficient of the first term is the leading coefficient. leading coefficient degree 2x 3 + x 2 5x + 12 constant term Writing a Polynomial in Standard Form Write 15x x in standard form. Identify the degree and leading coefficient of the polynomial. Consider the degree of each term of the polynomial. Degree is 3. Degree is 1. 15x x Degree is 0. You can write the polynomial in standard form as x x + 3. The greatest degree is 3, so the degree of the polynomial is 3, and the leading coefficient is 1. Classifying Polynomials Write each polynomial in standard form. Identify the degree and classify each polynomial by the number of terms. a. 3z 4 b x 2 x c. 8q + q 5 Polynomial Standard Form Degree Type of Polynomial a. 3z 4 3z 4 4 monomial b x 2 x 5x 2 x trinomial c. 8q + q 5 q 5 + 8q 5 binomial Monitoring Progress Help in English and Spanish at BigIdeasMath.com Write the polynomial in standard form. Identify the degree and leading coefficient of the polynomial. Then classify the polynomial by the number of terms z 6. t 2 t 3 10t x + x 3 Section 7.1 Adding and Subtracting Polynomials 359

7 Adding and Subtracting Polynomials A set of numbers is closed under an operation when the operation performed on any two numbers in the set results in a number that is also in the set. For example, the set of integers is closed under addition, subtraction, and multiplication. This means that if a and b are two integers, then a + b, a b, and ab are also integers. The set of polynomials is closed under addition and subtraction. So, the sum or difference of any two polynomials is also a polynomial. To add polynomials, add like terms. You can use a vertical or a horizontal format. Adding Polynomials STUDY TIP When a power of the variable appears in one polynomial but not the other, leave a space in that column, or write the term with a coefficient of 0. Find the sum. a. (2x 3 5x 2 + x) + (2x 2 + x 3 1) b. (3x 2 + x 6) + (x 2 + 4x + 10) a. Vertical format: Align like terms vertically and add. 2x 3 5x 2 + x + x 3 + 2x 2 1 3x 3 3x 2 + x 1 The sum is 3x 3 3x 2 + x 1. b. Horizontal format: Group like terms and simplify. (3x 2 + x 6) + (x 2 + 4x + 10) = (3x 2 + x 2 ) + (x + 4x) + ( ) The sum is 4x 2 + 5x + 4. = 4x 2 + 5x + 4 To subtract a polynomial, add its opposite. To find the opposite of a polynomial, multiply each of its terms by 1. Find the difference. Subtracting Polynomials COMMON ERROR Remember to multiply each term of the polynomial by 1 when you write the subtraction as addition. a. (4n 2 + 5) ( 2n 2 + 2n 4) b. (4x 2 3x + 5) (3x 2 x 8) a. Vertical format: Align like terms vertically and subtract. 4n n ( 2n 2 + 2n 4) + 2n 2 2n + 4 6n 2 2n + 9 The difference is 6n 2 2n + 9. b. Horizontal format: Group like terms and simplify. (4x 2 3x + 5) (3x 2 x 8) = 4x 2 3x + 5 3x 2 + x + 8 = (4x 2 3x 2 ) + ( 3x + x) + (5 + 8) = x 2 2x + 13 The difference is x 2 2x Chapter 7 Polynomial Equations and Factoring

8 Monitoring Progress Help in English and Spanish at BigIdeasMath.com Find the sum or difference. 8. (b 10) + (4b 3) 9. (x 2 x 2) + (7x 2 x) 10. (p 2 + p + 3) ( 4p 2 p + 3) 11. ( k + 5) (3k 2 6) Solving Real-Life Problems Solving a Real-Life Problem A penny is thrown straight down from a height of 200 feet. At the same time, a paintbrush is dropped from a height of 100 feet. The polynomials represent the heights (in feet) of the objects after t seconds. 16t 2 40t t Not drawn to scale a. Write a polynomial that represents the distance between the penny and the paintbrush after t seconds. b. Interpret the coefficients of the polynomial in part (a). a. To find the distance between the objects after t seconds, subtract the polynomials. Penny 16t 2 40t t 2 40t Paintbrush ( 16t ) + 16t t The polynomial 40t represents the distance between the objects after t seconds. b. When t = 0, the distance between the objects is 40(0) = 100 feet. So, the constant term 100 represents the distance between the penny and the paintbrush when both objects begin to fall. As the value of t increases by 1, the value of 40t decreases by 40. This means that the objects become 40 feet closer to each other each second. So, 40 represents the amount that the distance between the objects changes each second. Monitoring Progress Help in English and Spanish at BigIdeasMath.com 12. WHAT IF? The polynomial 16t 2 25t represents the height of the penny after t seconds. a. Write a polynomial that represents the distance between the penny and the paintbrush after t seconds. b. Interpret the coefficients of the polynomial in part (a). Section 7.1 Adding and Subtracting Polynomials 361

7.1 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. VOCABULARY When is a polynomial in one variable in standard form? 2.

9 7.1 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. VOCABULARY When is a polynomial in one variable in standard form? 2. OPEN-ENDED Write a trinomial in one variable of degree 5 in standard form. 3. VOCABULARY How can you determine whether a set of numbers is closed under an operation? 4. WHICH ONE DOESN T BELONG? Which expression does not belong with the other three? Explain your reasoning. π a 3 + 4a x 2 8 x b y8 z Monitoring Progress and Modeling with Mathematics In Exercises 5 12, find the degree of the monomial. (See Example 1.) 5. 4g 6. 23x k s 8 t 10. 8m 2 n xy 3 z q 4 rs 6 In Exercises 13 20, write the polynomial in standard form. Identify the degree and leading coefficient of the polynomial. Then classify the polynomial by the number of terms. (See Examples 2 and 3.) 13. 6c 2 + 2c 4 c 14. 4w 11 w p d 2 4d t z + 2z 3 + 3z πr r 8 + 2r n MODELING WITH MATHEMATICS The expression 4 3 πr3 represents the volume of a sphere with radius r. Why is this expression a monomial? What is its degree? 22. MODELING WITH MATHEMATICS The amount of money you have after investing $400 for 8 years and $600 for 6 years at the same interest rate is represented by 400x x 6, where x is the growth factor. Classify the polynomial by the number of terms. What is its degree? In Exercises 23 30, find the sum. (See Example 4.) 23. (5y + 4) + ( 2y + 6) 24. ( 8x 12) + (9x + 4) 25. (2n 2 5n 6) + ( n 2 3n + 11) 26. ( 3p 3 + 5p 2 2p) + ( p 3 8p 2 15p) 27. (3g 2 g) + (3g 2 8g + 4) 28. (9r 2 + 4r 7) + (3r 2 3r) 29. (4a a 3 3) + (2a 3 5a 2 + 8) 30. (s 3 2s 9) + (2s 2 6s 3 +s) In Exercises 31 38, find the difference. (See Example 5.) 31. (d 9) (3d 1) 32. (6x + 9) (7x + 1) 33. ( y 2 4y + 9) (3y 2 6y 9) 34. (4m 2 m + 2) ( 3m m + 4) 35. (k 3 7k + 2) (k 2 12) 36. ( r 10) ( 4r 3 + r 2 + 7r) 362 Chapter 7 Polynomial Equations and Factoring

The difference of two trinomials is a trinomial. 49. A binomial is a polynomial of degree 2. 50. The sum of two polynomials is a polynomial.

10 37. (t 4 t 2 + t) (12 9t 2 7t) 38. (4d 6d 3 + 3d 2 ) (10d 3 + 7d 2) ERROR ANALYSIS In Exercises 39 and 40, describe and correct the error in finding the sum or difference (x 2 + x) (2x 2 3x) = x 2 + x 2x 2 3x = (x 2 2x 2 ) + (x 3x) = x 2 2x x 3 4x x 3 + 8x 2 2x 3 + 4x The difference of two trinomials is a trinomial. 49. A binomial is a polynomial of degree The sum of two polynomials is a polynomial. MODELING WITH MATHEMATICS The polynomial 16t 2 + v 0 t + s 0 represents the height (in feet) of an object, where v 0 is the initial vertical velocity (in feet per second), s 0 is the initial height of the object (in feet), and t is the time (in seconds). In Exercises 51 and 52, write a polynomial that represents the height of the object. Then find the height of the object after 1 second. 51. You throw a water 52. You bounce a tennis balloon from a building. ball on a racket. v 0 = 45 ft/sec v 0 = 16 ft/sec 41. MODELING WITH MATHEMATICS The cost (in dollars) of making b bracelets is represented by 4 + 5b. The cost (in dollars) of making b necklaces is represented by 8b + 6. Write a polynomial that represents how much more it costs to make b necklaces than b bracelets. s 0 = 200 ft s 0 = 3 ft Not drawn to scale 42. MODELING WITH MATHEMATICS The number of individual memberships at a fitness center in m months is represented by m. The number of family memberships at the fitness center in m months is represented by m. Write a polynomial that represents the total number of memberships at the fitness center. 53. MODELING WITH MATHEMATICS You drop a ball from a height of 98 feet. At the same time, your friend throws a ball upward. The polynomials represent the heights (in feet) of the balls after t seconds. (See Example 6.) 16t In Exercises 43 46, find the sum or difference. 43. (2s 2 5st t 2 ) (s 2 + 7st t 2 ) 44. (a 2 3ab + 2b 2 ) + ( 4a 2 + 5ab b 2 ) 45. (c 2 6d 2 ) + (c 2 2cd + 2d 2 ) 46. ( x 2 + 9xy) (x 2 + 6xy 8y 2 ) REASONING In Exercises 47 50, complete the statement with always, sometimes, or never. Explain your reasoning. 47. The terms of a polynomial are monomials. 16t t + 6 Not drawn to scale a. Before the balls reach the same height, write a polynomial that represents the distance between your ball and your friend s ball after t seconds. b. Interpret the coefficients of the polynomial in part (a). Section 7.1 Adding and Subtracting Polynomials 363

54. MODELING WITH MATHEMATICS During a 7-year period, the amounts (in millions of dollars) spent each year on buying new vehicles N and used vehicles U by United States residents are modeled by the

5t + 42 under the given operation. Explain. a. the set of negative integers; multiplication where t = 1 represents the first year in the 7-year period. b. the set of whole numbers; addition a.

x ftt 10 ft 10 ft 55. MATHEMATICAL CONNECTIONS 3x 2 Write the polynomial in standard form that represents the perimeter of the quadrilateral. l vel leve level lev ell 1 2x + 1 2x 5x 2 a.

11 54. MODELING WITH MATHEMATICS During a 7-year period, the amounts (in millions of dollars) spent each year on buying new vehicles N and used vehicles U by United States residents are modeled by the equations 58. THOUGHT PROVOKING Write two polynomials whose sum is x2 and whose difference is REASONING Determine whether the set is closed N = 0.028t t t + 17 U = 0.38t t + 42 under the given operation. Explain. a. the set of negative integers; multiplication where t = 1 represents the first year in the 7-year period. b. the set of whole numbers; addition a. Write a polynomial that represents the total amount spent each year on buying new and used vehicles in the 7-year period. 60. PROBLEM SOLVING You are building a multi-level deck. b. How much is spent on buying new and used vehicles in the fifth year? x ftt 10 ft 10 ft 55. MATHEMATICAL CONNECTIONS 3x 2 Write the polynomial in standard form that represents the perimeter of the quadrilateral. l vel leve level lev ell 1 2x + 1 2x 5x 2 a. For each level, write a polynomial in standard form that represents the area of that level. Then write the polynomial in standard form that represents the total area of the deck. 56. HOW DO YOU SEE IT? The right side of the equation of each line is a polynomial. 4 b. What is the total area of the deck when x = 20? y c. A gallon of deck sealant covers 400 square feet. How many gallons of sealant do you need to cover the deck in part (b) once? Explain. y = 2x ( 12) ft (x le eve ev vel 2 x ft 61. PROBLEM SOLVING A hotel installs a new swimming 2 4 x pool and a new hot tub. y=x 2 (8x 10) ft 4 patio 2x ft (6x 14) ft a. The absolute value of the difference of the two polynomials represents the vertical distance between points on the lines with the same x-value. Write this expression. pool b. When does the expression in part (a) equal 0? How does this value relate to the graph? 2x ft a. Write the polynomial in standard form that represents the area of the patio. 57. MAKING AN ARGUMENT Your friend says that when b. The patio will cost $10 per square foot. Determine the cost of the patio when x = 9. adding polynomials, the order in which you add does not matter. Is your friend correct? Explain. Maintaining Mathematical Proficiency x ft hot tub x ft Reviewing what you learned in previous grades and lessons Simplify the expression. (Skills Review Handbook) 62. 2(x 1) + 3(x + 2) 364 Chapter 7 hsnb_alg1_pe_0701.indd (4y 3) + 2(y 5) 64. 5(2r + 1) 3( 4r + 2) Polynomial Equations and Factoring 2/5/15 8:11 AM

12 7.2 Multiplying Polynomials Essential Question How can you multiply two polynomials? Multiplying Monomials Using Algebra Tiles Work with a partner. Write each product. Explain your reasoning. a. = b. = REASONING ABSTRACTLY To be proficient in math, you need to reason abstractly and quantitatively. You need to pause as needed to recall the meanings of the symbols, operations, and quantities involved. c. = d. = e. = f. = g. = h. = i. = j. = Multiplying Binomials Using Algebra Tiles Work with a partner. Write the product of two binomials modeled by each rectangular array of algebra tiles. In parts (c) and (d), first draw the rectangular array of algebra tiles that models each product. a. (x + 3)(x 2) = b. (2x 1)(2x + 1) = c. (x + 2)(2x 1) = d. ( x 2)(x 3) = Communicate Your Answer 3. How can you multiply two polynomials? 4. Give another example of multiplying two binomials using algebra tiles that is similar to those in Exploration 2. Section 7.2 Multiplying Polynomials 365

13 7.2 Lesson What You Will Learn Core Vocabulary FOIL Method, p. 367 Previous polynomial closed binomial trinomial Multiply binomials. Use the FOIL Method. Multiply binomials and trinomials. Multiplying Binomials The product of two polynomials is always a polynomial. So, like the set of integers, the set of polynomials is closed under multiplication. You can use the Distributive Property to multiply two binomials. Multiplying Binomials Using the Distributive Property Find (a) (x + 2)(x + 5) and (b) (x + 3)(x 4). a. Use the horizontal method. (x + 2)(x + 5) = x(x + 5) + 2(x + 5) Distribute (x + 5) to each term of (x + 2). = x(x) + x(5) + 2(x) + 2(5) Distributive Property = x 2 + 5x + 2x + 10 Multiply. = x 2 + 7x + 10 Combine like terms. The product is x 2 + 7x b. Use the vertical method. Multiply 4(x + 3). Multiply x(x + 3). The product is x 2 x 12. x + 3 x 4 Align like terms vertically. 4x 12 Distributive Property x 2 + 3x Distributive Property x 2 x 12 Combine like terms. Find (2x 3)(x + 5). Multiplying Binomials Using a Table Step 1 Write each binomial as a sum of terms. (2x 3)(x + 5) = [2x + ( 3)](x + 5) Step 2 Make a table of products. The product is 2x 2 3x + 10x 15, or 2x 2 + 7x 15. 2x 3 x 2x 2 3x 5 10x 15 Monitoring Progress Help in English and Spanish at BigIdeasMath.com Use the Distributive Property to find the product. 1. (y + 4)(y + 1) 2. (z 2)(z + 6) Use a table to find the product. 3. (p + 3)(p 8) 4. (r 5)(2r 1) 366 Chapter 7 Polynomial Equations and Factoring

14 Using the FOIL Method The FOIL Method is a shortcut for multiplying two binomials. Core Concept FOIL Method To multiply two binomials using the FOIL Method, find the sum of the products of the First terms, (x + 1)(x + 2) x(x) = x 2 Outer terms, (x + 1)(x + 2) x(2) = 2x Inner terms, and (x + 1)(x + 2) 1(x) = x Last terms. (x + 1)(x + 2) 1(2) = 2 (x + 1)(x + 2) = x 2 + 2x + x + 2 = x 2 + 3x + 2 Multiplying Binomials Using the FOIL Method Find each product. a. (x 3)(x 6) b. (2x + 1)(3x 5) a. Use the FOIL Method. First Outer Inner Last (x 3)(x 6) = x(x) + x( 6) + ( 3)(x) + ( 3)( 6) FOIL Method = x 2 + ( 6x) + ( 3x) + 18 Multiply. = x 2 9x + 18 Combine like terms. The product is x 2 9x b. Use the FOIL Method. First Outer Inner Last (2x + 1)(3x 5) = 2x(3x) + 2x( 5) + 1(3x) + 1( 5) FOIL Method = 6x 2 + ( 10x) + 3x + ( 5) Multiply. = 6x 2 7x 5 Combine like terms. The product is 6x 2 7x 5. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Use the FOIL Method to find the product. 5. (m 3)(m 7) 6. (x 4)(x + 2) 7. ( 2u ) ( u 3 2 ) 8. (n + 2)(n 2 + 3) Section 7.2 Multiplying Polynomials 367

15 Multiplying Binomials and Trinomials Multiplying a Binomial and a Trinomial Find (x + 5)(x 2 3x 2). x 2 3x 2 Multiply 5(x 2 3x 2). Multiply x(x 2 3x 2). x + 5 Align like terms vertically. 5x 2 15x 10 Distributive Property x 3 3x 2 2x Distributive Property x 3 + 2x 2 17x 10 Combine like terms. The product is x 3 + 2x 2 17x 10. Solving a Real-Life Problem In hockey, a goalie behind the goal line can only play a puck in the trapezoidal region. a. Write a polynomial that represents the area of the trapezoidal region. b. Find the area of the trapezoidal region when the shorter base is 18 feet. a. 1 2 h(b 1 + b 2 ) = 1 (x 7)[x + (x + 10)] Substitute. 2 = 1 (x 7)(2x + 10) Combine like terms. 2 x ft (x 7) ft (x + 10) ft F O I L = 1 2 [2x2 + 10x + ( 14x) + ( 70)] FOIL Method = 1 2 (2x2 4x 70) Combine like terms. = x 2 2x 35 Distributive Property A polynomial that represents the area of the trapezoidal region is x 2 2x 35. b. Find the value of x 2 2x 35 when x = 18. x 2 2x 35 = (18) 35 Substitute 18 for x. = Simplify. = 253 Subtract. The area of the trapezoidal region is 253 square feet. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Find the product. 9. (x + 1)(x 2 + 5x + 8) 10. (n 3)(n 2 2n + 4) 11. WHAT IF? In Example 5(a), how does the polynomial change when the longer base is extended by 1 foot? Explain. 368 Chapter 7 Polynomial Equations and Factoring

7.2 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. VOCABULARY Describe two ways to find the product of two binomials. 2.

16 7.2 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. VOCABULARY Describe two ways to find the product of two binomials. 2. WRITING Explain how the letters of the word FOIL can help you to remember how to multiply two binomials. Monitoring Progress and Modeling with Mathematics In Exercises 3 10, use the Distributive Property to find the product. (See Example 1.) 3. (x + 1)(x + 3) 4. (y + 6)(y + 4) 5. (z 5)(z + 3) 6. (a + 8)(a 3) 7. (g 7)(g 2) 8. (n 6)(n 4) 9. (3m + 1)(m + 9) 10. (5s + 6)(s 2) In Exercises 11 18, use a table to find the product. (See Example 2.) 11. (x + 3)(x + 2) 12. (y + 10)(y 5) 13. (h 8)(h 9) 14. (c 6)(c 5) 15. (3k 1)(4k + 9) 16. (5g + 3)(g + 8) 17. ( 3 + 2j)(4j 7) 18. (5d 12)( 7 + 3d ) ERROR ANALYSIS In Exercises 19 and 20, describe and correct the error in finding the product of the binomials. In Exercises 21 30, use the FOIL Method to find the product. (See Example 3.) 21. (b + 3)(b + 7) 22. (w + 9)(w + 6) 23. (k + 5)(k 1) 24. (x 4)(x + 8) 25. ( q 3 4 ) ( q ) 26. ( z 5 3 ) ( z 2 3 ) 27. (9 r)(2 3r) 28. (8 4x)(2x + 6) 29. (w + 5)(w 2 + 3w) 30. (v 3)(v 2 + 8v) MATHEMATICAL CONNECTIONS In Exercises 31 34, write a polynomial that represents the area of the shaded region x 9 x p + 1 2p (t 2)(t + 5) = t 2(t + 5) = t 2t 10 = t x x + 1 x 7 5 x + 1 x (x 5)(3x + 1) 3x 1 x 3x 2 x 5 15x 5 In Exercises 35 42, find the product. (See Example 4.) 35. (x + 4)(x 2 + 3x + 2) 36. ( f + 1)( f 2 + 4f + 8) 37. (y + 3)( y 2 + 8y 2) 38. (t 2)(t 2 5t + 1) (x 5)(3x + 1) = 3x x (4 b)(5b 2 + 5b 4) 40. (d + 6)(2d 2 d + 7) 41. (3e 2 5e + 7)(6e + 1) 42. (6v 2 + 2v 9)(4 5v) Section 7.2 Multiplying Polynomials 369

17 43. MODELING WITH MATHEMATICS The football field is rectangular. (See Example 5.) (10x + 10) ft (4x + 20) ft a. Write a polynomial that represents the area of the football field. b. Find the area of the football field when the width is 160 feet. 44. MODELING WITH MATHEMATICS You design a frame to surround a rectangular photo. The width of the frame is the same on every side, as shown. 20 in. x in. 47. MAKING AN ARGUMENT Your friend says the FOIL Method can be used to multiply two trinomials. Is your friend correct? Explain your reasoning. 48. HOW DO YOU SEE IT? The table shows one method of finding the product of two binomials. 4x 3 8x a b 9 c d a. Write the two binomials being multiplied. b. Determine whether a, b, c, and d will be positive or negative when x > COMPARING METHODS You use the Distributive Property to multiply (x + 3)(x 5). Your friend uses the FOIL Method to multiply (x 5)(x + 3). Should your answers be equivalent? Justify your answer. 50. USING STRUCTURE The shipping container is a rectangular prism. Write a polynomial that represents the volume of the container. x in. x in. 22 in. x in. a. Write a polynomial that represents the combined area of the photo and the frame. b. Find the combined area of the photo and the frame when the width of the frame is 4 inches. 45. WRITING When multiplying two binomials, explain how the degree of the product is related to the degree of each binomial. 46. THOUGHT PROVOKING Write two polynomials that are not monomials whose product is a trinomial of degree 3. (4x 3) ft (x + 1) ft (x + 2) ft 51. ABSTRACT REASONING The product of (x + m)(x + n) is x 2 + bx + c. a. What do you know about m and n when c > 0? b. What do you know about m and n when c < 0? Maintaining Mathematical Proficiency Reviewing what you learned in previous grades and lessons Write the absolute value function as a piecewise function. (Section 4.7) 52. y = x y = 6 x y = 4 x + 2 Simplify the expression. Write your answer using only positive exponents. (Section 6.1) x 5 x x (3z 6 ) ( 2y4 y ) Chapter 7 Polynomial Equations and Factoring

18 7.3 Special Products of Polynomials Essential Question What are the patterns in the special products (a + b)(a b), (a + b) 2, and (a b) 2? Finding a Sum and Difference Pattern Work with a partner. Write the product of two binomials modeled by each rectangular array of algebra tiles. a. (x + 2)(x 2) = b. (2x 1)(2x + 1) = Finding the Square of a Binomial Pattern Work with a partner. Draw the rectangular array of algebra tiles that models each product of two binomials. Write the product. a. (x + 2) 2 = b. (2x 1) 2 = LOOKING FOR STRUCTURE To be proficient in math, you need to look closely to discern a pattern or structure. Communicate Your Answer 3. What are the patterns in the special products (a + b)(a b), (a + b) 2, and (a b) 2? 4. Use the appropriate special product pattern to find each product. Check your answers using algebra tiles. a. (x + 3)(x 3) b. (x 4)(x + 4) c. (3x + 1)(3x 1) d. (x + 3) 2 e. (x 2) 2 f. (3x + 1) 2 Section 7.3 Special Products of Polynomials 371

19 7.3 Lesson What You Will Learn Use the square of a binomial pattern. Core Vocabulary Previous binomial Use the sum and difference pattern. Use special product patterns to solve real-life problems. Using the Square of a Binomial Pattern The diagram shows a square with a side length of (a + b) units. You can see that the area of the square is a b (a + b) 2 = a 2 + 2ab + b 2. a a 2 ab This is one version of a pattern called the square of a binomial. To find another version of this pattern, use algebra: replace b with b. b ab b 2 (a + ( b)) 2 = a 2 + 2a( b) + ( b) 2 Replace b with b in the pattern above. (a b) 2 = a 2 2ab + b 2 Simplify. Core Concept Square of a Binomial Pattern Algebra Example (a + b) 2 = a 2 + 2ab + b 2 (x + 5) 2 = (x) 2 + 2(x)(5) + (5) 2 = x x + 25 (a b) 2 = a 2 2ab + b 2 (2x 3) 2 = (2x) 2 2(2x)(3) + (3) 2 = 4x 2 12x + 9 LOOKING FOR STRUCTURE When you use special product patterns, remember that a and b can be numbers, variables, or variable expressions. Using the Square of a Binomial Pattern Find each product. a. (3x + 4) 2 b. (5x 2y) 2 a. (3x + 4) 2 = (3x) 2 + 2(3x)(4) Square of a binomial pattern = 9x x + 16 Simplify. The product is 9x x b. (5x 2y) 2 = (5x) 2 2(5x)(2y) + (2y) 2 Square of a binomial pattern = 25x 2 20xy + 4y 2 Simplify. The product is 25x 2 20xy + 4y 2. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Find the product. 1. (x + 7) 2 2. (7x 3) 2 3. (4x y) 2 4. (3m + n) Chapter 7 Polynomial Equations and Factoring

20 Using the Sum and Difference Pattern To find the product (x + 2)(x 2), you can multiply the two binomials using the FOIL Method. (x + 2)(x 2) = x 2 2x + 2x 4 FOIL Method = x 2 4 Combine like terms. This suggests a pattern for the product of the sum and difference of two terms. Core Concept Sum and Difference Pattern Algebra Example (a + b)(a b) = a 2 b 2 (x + 3)(x 3) = x 2 9 Using the Sum and Difference Pattern Find each product. a. (t + 5)(t 5) b. (3x + y)(3x y) a. (t + 5)(t 5) = t Sum and difference pattern = t 2 25 Simplify. The product is t b. (3x + y)(3x y) = (3x) 2 y 2 Sum and difference pattern = 9x 2 y 2 Simplify. The product is 9x 2 y 2. The special product patterns can help you use mental math to find certain products of numbers. Using Special Product Patterns and Mental Math Use special product patterns to find the product Notice that 26 is 4 less than 30, while 34 is 4 more than = (30 4)(30 + 4) Write as product of difference and sum. = Sum and difference pattern = Evaluate powers. = 884 Simplify. The product is 884. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Find the product. 5. (x + 10)(x 10) 6. (2x + 1)(2x 1) 7. (x + 3y)(x 3y) 8. Describe how to use special product patterns to find Section 7.3 Special Products of Polynomials 373

21 Solving Real-Life Problems Modeling with Mathematics A combination of two genes determines the color of the dark patches of a border collie s coat. An offspring inherits one patch color gene from each parent. Each parent has two color genes, and the offspring has an equal chance of inheriting either one. The gene B is for black patches, and the gene r is for red patches. Any gene combination with a B results in black patches. Suppose each parent has the same gene combination Br. The Punnett square shows the possible gene combinations of the offspring and the resulting patch colors. Parent Br B r Parent a. What percent of the possible gene combinations result in black patches? b. Show how you could use a polynomial to model the possible gene combinations. a. Notice that the Punnett square shows four possible gene combinations of the offspring. Of these combinations, three result in black patches. So, 75% of the possible gene combinations result in black patches. b. Model the gene from each parent with 0.5B + 0.5r. There is an equal chance that the offspring inherits a black or a red gene from each parent. You can model the possible gene combinations of the offspring with (0.5B + 0.5r) 2. Notice that this product also represents the area of the Punnett square. Expand the product to find the possible patch colors of the offspring. (0.5B + 0.5r) 2 = (0.5B) 2 + 2(0.5B)(0.5r) + (0.5r) 2 = 0.25B Br r 2 Consider the coefficients in the polynomial. 0.25B Br r 2 B BB Br Br r Br rr 25% BB, black patches 50% Br, black patches 25% rr, red patches BW B W B BB black BW gray BW W BW gray WW white The coefficients show that 25% + 50% = 75% of the possible gene combinations result in black patches. Monitoring Progress Help in English and Spanish at BigIdeasMath.com 9. Each of two dogs has one black gene (B) and one white gene (W). The Punnett square shows the possible gene combinations of an offspring and the resulting colors. a. What percent of the possible gene combinations result in black? b. Show how you could use a polynomial to model the possible gene combinations of the offspring. 374 Chapter 7 Polynomial Equations and Factoring

22 7.3 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. WRITING Explain how to use the square of a binomial pattern. 2. WHICH ONE DOESN T BELONG? Which expression does not belong with the other three? Explain your reasoning. (x + 1)(x 1) (3x + 2)(3x 2) (x + 2)(x 3) (2x + 5)(2x 5) Monitoring Progress and Modeling with Mathematics In Exercises 3 10, find the product. (See Example 1.) 3. (x + 8) 2 4. (a 6) 2 5. (2f 1) 2 6. (5p + 2) 2 7. ( 7t + 4) 2 8. ( 12 n) 2 9. (2a + b) (6x 3y) 2 MATHEMATICAL CONNECTIONS In Exercises 11 14, write a polynomial that represents the area of the square. 11. x x 7 x x x In Exercises 25 30, use special product patterns to find the product. (See Example 3.) ERROR ANALYSIS In Exercises 31 and 32, describe and correct the error in finding the product. 31. (k + 4) 2 = k = k x 32. (s + 5)(s 5) = s 2 + 2(s)(5) 5 2 = s s n c + 4d 33. MODELING WITH MATHEMATICS A contractor extends a house on two sides. In Exercises 15 24, find the product. (See Example 2.) 15. (t 7)(t + 7) 16. (m + 6)(m 6) 17. (4x + 1)(4x 1) 18. (2k 4)(2k + 4) 19. (8 + 3a)(8 3a) 20. ( 1 2 c ) ( c ) 21. (p 10q)(p + 10q) 22. (7m + 8n)(7m 8n) a. The area of the house after the renovation is represented by (x + 50) 2. Find this product. b. Use the polynomial in part (a) to find the area when x = 15. What is the area of the extension? 23. ( y + 4)( y 4) 24. ( 5g 2h)( 5g + 2h) Section 7.3 Special Products of Polynomials 375

23 34. MODELING WITH MATHEMATICS A square-shaped parking lot with 100-foot sides is reduced by x feet on one side and extended by x feet on an adjacent side. a. The area of the new parking lot is represented by (100 x)(100 + x). Find this product. b. Does the area of the parking lot increase, decrease, or stay the same? Explain. c. Use the polynomial in part (a) to find the area of the new parking lot when x = MODELING WITH MATHEMATICS In deer, the gene N is for normal coloring and the gene a is for no coloring, or albino. Any gene combination with an N results in normal coloring. The Punnett square shows the possible gene combinations of an offspring and the resulting colors from parents that both have the gene combination Na. (See Example 4.) a. What percent of the possible gene combinations result in albino coloring? b. Show how you could use a polynomial to model the possible gene combinations of the offspring. 36. MODELING WITH MATHEMATICS Your iris controls the amount of light that enters your eye by changing the size of your pupil. pupil 6 mm x Parent B iris Na a. Write a polynomial that represents the area of your pupil. Write your answer in terms of π. b. The width x of your iris decreases from 4 millimeters to 2 millimeters when you enter a dark room. How many times greater is the area of your pupil after entering the room than before entering the room? Explain. N a N NN normal Na normal Parent A Na a Na normal aa albino 38. HOW DO YOU SEE IT? In pea plants, any gene combination with a green gene (G) results in a green pod. The Punnett square shows the possible gene combinations of the offspring of two Gy pea plants and the resulting pod colors. Gy G y GG Gy G Gy Gy yy y A polynomial that models the possible gene combinations of the offspring is (0.5G + 0.5y) 2 = 0.25G Gy y 2. Describe two ways to determine the percent of possible gene combinations that result in green pods. In Exercises 39 42, find the product. 39. (x 2 + 1)(x 2 1) 40. (y 3 + 4) 2 G = Green gene y = Yellow gene 41. (2m 2 5n 2 ) (r 3 6t 4 )(r 3 + 6t 4 ) 43. MAKING AN ARGUMENT Your friend claims to be able to use a special product pattern to determine that ( ) 2 is equal to Is your friend correct? Explain THOUGHT PROVOKING The area (in square meters) of the surface of an artificial lake is represented by x 2. Describe three ways to modify the dimensions of the lake so that the new area can be represented by the three types of special product patterns discussed in this section. 45. REASONING Find k so that 9x 2 48x + k is the square of a binomial. 46. REPEATED REASONING Find (x + 1) 3 and (x + 2) 3. Find a pattern in the terms and use it to write a pattern for the cube of a binomial (a + b) CRITICAL THINKING Write two binomials that have the product x Explain. Maintaining Mathematical Proficiency Factor the expression using the GCF. (Skills Review Handbook) 47. PROBLEM SOLVING Find two numbers a and b such that (a + b)(a b) < (a b) 2 < (a + b) 2. Reviewing what you learned in previous grades and lessons y r s + 35t x 10y 376 Chapter 7 Polynomial Equations and Factoring

24 7.4 Solving Polynomial Equations in Factored Form Essential Question How can you solve a polynomial equation? Matching Equivalent Forms of an Equation Work with a partner. An equation is considered to be in factored form when the product of the factors is equal to 0. Match each factored form of the equation with its equivalent standard form and nonstandard form. Factored Form Standard Form Nonstandard Form a. (x 1)(x 3) = 0 A. x 2 x 2 = 0 1. x 2 5x = 6 USING TOOLS STRATEGICALLY To be proficient in math, you need to consider using tools such as a table or a spreadsheet to organize your results. b. (x 2)(x 3) = 0 B. x 2 + x 2 = 0 2. (x 1) 2 = 4 c. (x + 1)(x 2) = 0 C. x 2 4x + 3 = 0 3. x 2 x = 2 d. (x 1)(x + 2) = 0 D. x 2 5x + 6 = 0 4. x(x + 1) = 2 e. (x + 1)(x 3) = 0 E. x 2 2x 3 = 0 5. x 2 4x = 3 Writing a Conjecture Work with a partner. Substitute 1, 2, 3, 4, 5, and 6 for x in each equation and determine whether the equation is true. Organize your results in a table. Write a conjecture describing what you discovered. a. (x 1)(x 2) = 0 b. (x 2)(x 3) = 0 c. (x 3)(x 4) = 0 d. (x 4)(x 5) = 0 e. (x 5)(x 6) = 0 f. (x 6)(x 1) = 0 Special Properties of 0 and 1 Work with a partner. The numbers 0 and 1 have special properties that are shared by no other numbers. For each of the following, decide whether the property is true for 0, 1, both, or neither. Explain your reasoning. a. When you add to a number n, you get n. b. If the product of two numbers is, then at least one of the numbers is 0. c. The square of is equal to itself. d. When you multiply a number n by, you get n. e. When you multiply a number n by, you get 0. f. The opposite of is equal to itself. Communicate Your Answer 4. How can you solve a polynomial equation? 5. One of the properties in Exploration 3 is called the Zero-Product Property. It is one of the most important properties in all of algebra. Which property is it? Why do you think it is called the Zero-Product Property? Explain how it is used in algebra and why it is so important. Section 7.4 Solving Polynomial Equations in Factored Form 377

25 7.4 Lesson What You Will Learn Core Vocabulary factored form, p. 378 Zero-Product Property, p. 378 roots, p. 378 repeated roots, p. 379 Previous polynomial standard form greatest common factor (GCF) monomial Use the Zero-Product Property. Factor polynomials using the GCF. Use the Zero-Product Property to solve real-life problems. Using the Zero-Product Property A polynomial is in factored form when it is written as a product of factors. Standard form Factored form x 2 + 2x x(x + 2) x 2 + 5x 24 (x 3)(x + 8) When one side of an equation is a polynomial in factored form and the other side is 0, use the Zero-Product Property to solve the polynomial equation. The solutions of a polynomial equation are also called roots. Core Concept Zero-Product Property Words If the product of two real numbers is 0, then at least one of the numbers is 0. Algebra If a and b are real numbers and ab = 0, then a = 0 or b = 0. Solving Polynomial Equations Solve each equation. a. 2x(x 4) = 0 b. (x 3)(x 9) = 0 Check To check the solutions of Example 1(a), substitute each solution in the original equation. 2(0)(0 4) =? 0 0( 4) =? 0 0 = 0 2(4)(4 4) =? 0 8(0) =? 0 0 = 0 a. 2x(x 4) = 0 Write equation. 2x = 0 or x 4 = 0 Zero-Product Property x = 0 or x = 4 Solve for x. The roots are x = 0 and x = 4. b. (x 3)(x 9) = 0 Write equation. x 3 = 0 or x 9 = 0 Zero-Product Property x = 3 or x = 9 Solve for x. The roots are x = 3 and x = 9. Monitoring Progress Solve the equation. Check your solutions. 1. x(x 1) = t(t + 2) = 0 3. (z 4)(z 6) = 0 Help in English and Spanish at BigIdeasMath.com 378 Chapter 7 Polynomial Equations and Factoring

26 When two or more roots of an equation are the same number, the equation has repeated roots. Solving Polynomial Equations Solve each equation. a. (2x + 7)(2x 7) = 0 b. (x 1) 2 = 0 c. (x + 1)(x 3)(x 2) = 0 a. (2x + 7)(2x 7) = 0 Write equation. 2x + 7 = 0 or 2x 7 = 0 Zero-Product Property 7 x = 2 or x = 7 2 Solve for x. STUDY TIP You can extend the Zero-Product Property to products of more than two real numbers. The roots are x = 2 and x = 7 7 b. (x 1) 2 = 0 Write equation. (x 1)(x 1) = 0 Expand equation. x 1 = 0 or x 1 = 0 Zero-Product Property x = 1 or x = 1 Solve for x. The equation has repeated roots of x = 1. c. (x + 1)(x 3)(x 2) = 0 Write equation. x + 1 = 0 or x 3 = 0 or x 2 = 0 Zero-Product Property x = 1 or x = 3 or x = 2 Solve for x. The roots are x = 1, x = 3, and x = Monitoring Progress Solve the equation. Check your solutions. Help in English and Spanish at BigIdeasMath.com 4. (3s + 5)(5s + 8) = 0 5. (b + 7) 2 = 0 6. (d 2)(d + 6)(d + 8) = 0 Factoring Polynomials Using the GCF To solve a polynomial equation using the Zero-Product Property, you may need to factor the polynomial, or write it as a product of other polynomials. Look for the greatest common factor (GCF) of the terms of the polynomial. This is a monomial that divides evenly into each term. Finding the Greatest Common Monomial Factor Factor out the greatest common monomial factor from 4x x 3. The GCF of 4 and 24 is 4. The GCF of x 4 and x 3 is x 3. So, the greatest common monomial factor of the terms is 4x 3. So, 4x x 3 = 4x 3 (x + 6). Monitoring Progress Help in English and Spanish at BigIdeasMath.com 7. Factor out the greatest common monomial factor from 8y 2 24y. Section 7.4 Solving Polynomial Equations in Factored Form 379

27 Solving Equations by Factoring Solve (a) 2x 2 + 8x = 0 and (b) 6n 2 = 15n. a. 2x 2 + 8x = 0 Write equation. 2x(x + 4) = 0 2x = 0 or x + 4 = 0 Factor left side. Zero-Product Property x = 0 or x = 4 Solve for x. The roots are x = 0 and x = 4. b. 6n 2 = 15n Write equation. 6n 2 15n = 0 3n(2n 5) = 0 3n = 0 or 2n 5 = 0 Subtract 15n from each side. Factor left side. Zero-Product Property n = 0 or n = 5 2 Solve for n. The roots are n = 0 and n = 5 2. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Solve the equation. Check your solutions. 8. a 2 + 5a = s 2 9s = x 2 = 2x Solving Real-Life Problems Modeling with Mathematics 40 y You can model the arch of a fireplace using the equation y = 9 ( x + 18)(x 18), where x and y are measured in inches. The x-axis represents the floor. Find the width of the arch at floor level x Use the x-coordinates of the points where the arch meets the floor to find the width. At floor level, y = 0. So, substitute 0 for y and solve for x. 1 y = (x + 18)(x 18) Write equation. 0 = (x + 18)(x 18) Substitute 0 for y. 0 = (x + 18)(x 18) Multiply each side by 9. x + 18 = 0 or x 18 = 0 Zero-Product Property x = 18 or x = 18 Solve for x. The width is the distance between the x-coordinates, 18 and 18. So, the width of the arch at floor level is = 36 inches. Monitoring Progress Help in English and Spanish at BigIdeasMath.com 11. You can model the entrance to a mine shaft using the equation 1 2 y = (x + 4)(x 4), where x and y are measured in feet. The x-axis represents the ground. Find the width of the entrance at ground level. 380 Chapter 7 Polynomial Equations and Factoring

28 7.4 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. WRITING Explain how to use the Zero-Product Property to find the solutions of the equation 3x(x 6) = DIFFERENT WORDS, SAME QUESTION Which is different? Find both answers. Solve the equation (2k + 4)(k 3) = 0. Find the values of k for which 2k + 4 = 0 or k 3 = 0. Find the value of k for which (2k + 4) + (k 3) = 0. Find the roots of the equation (2k + 4)(k 3) = 0. Monitoring Progress and Modeling with Mathematics In Exercises 3 8, solve the equation. (See Example 1.) 23. y 24. y 3. x(x + 7) = 0 4. r(r 10) = t(t 5) = v(v + 1) = (s 9)(s 1) = 0 8. (y + 2)(y 6) = 0 In Exercises 9 20, solve the equation. (See Example 2.) 9. (2a 6)(3a + 15) = (4q + 3)(q + 2) = x x 11. (5m + 4) 2 = (h 8) 2 = 0 y = (x 14)(x 5) y = 0.2(x + 22)(x 15) 13. (3 2g)(7 g) = (2 4d )(2 + 4d ) = z(z + 2)(z 1) = p(2p 3)( p + 7) = (r 4) 2 (r + 8) = w(w 6) 2 = (15 5c)(5c + 5)( c + 6) = (2 n) ( n ) (n 2) = 0 In Exercises 21 24, find the x-coordinates of the points where the graph crosses the x-axis. In Exercises 25 30, factor the polynomial. (See Example 3.) 25. 5z z 26. 6d 2 21d 27. 3y 3 9y x x n 6 + 2n a 4 + 8a In Exercises 31 36, solve the equation. (See Example 4.) 31. 4p 2 p = m m = y = (x 8)(x + 8) 22. y = (x + 1)(x + 7) c + 10c 2 = q 2q 2 = 0 99 y 3 9 x 6 y 35. 3n 2 = 9n r = 4r x 37. ERROR ANALYSIS Describe and correct the error in solving the equation. 6x(x + 5) = 0 x + 5 = 0 8 x = 5 The root is x = 5. Section 7.4 Solving Polynomial Equations in Factored Form 381

38. ERROR ANALYSIS Describe and correct the error in 41. MODELING WITH MATHEMATICS A penguin leaps solving the equation. out of the water while swimming. This action is called porpoising.

Explain what the roots mean in this situation. 3y2 = 21y 3y = 21 y=7 The root is y = 7. 42. HOW DO YOU SEE IT? Use the graph to fill in each blank in the equation with the symbol + or.

29 38. ERROR ANALYSIS Describe and correct the error in 41. MODELING WITH MATHEMATICS A penguin leaps solving the equation. out of the water while swimming. This action is called porpoising. The height y (in feet) of a porpoising penguin can be modeled by y = 16x x, where x is the time (in seconds) since the penguin leaped out of the water. Find the roots of the equation when y = 0. Explain what the roots mean in this situation. 3y2 = 21y 3y = 21 y=7 The root is y = HOW DO YOU SEE IT? Use the graph to fill in each blank in the equation with the symbol + or. Explain your reasoning. 39. MODELING WITH MATHEMATICS The entrance of a 11 tunnel can be modeled by y = (x 4)(x 24), 50 where x and y are measured in feet. The x-axis represents the ground. Find the width of the tunnel at ground level. (See Example 5.) y x y y = (x 8 5)(x 3) x CRITICAL THINKING How many x-intercepts does the graph of y = (2x + 5)(x 9)2 have? Explain. 40. MODELING WITH MATHEMATICS The Gateway Arch in St. Louis can be modeled by 2 y = (x + 315)(x 315), where x and y are 315 measured in feet. The x-axis represents the ground MAKING AN ARGUMENT Your friend says that the graph of the equation y = (x a)(x b) always has two x-intercepts for any values of a and b. Is your friend correct? Explain. y 45. CRITICAL THINKING Does the equation tallest point (x2 + 3)(x 4 + 1) = 0 have any real roots? Explain. 46. THOUGHT PROVOKING Write a polynomial equation 400 of degree 4 whose only roots are x = 1, x = 2, and x = REASONING Find the values of x in terms of y that x are solutions of each equation. a. (x + y)(2x y) = 0 a. Find the width of the arch at ground level. b. (x2 y2)(4x + 16y) = 0 b. How tall is the arch? 48. PROBLEM SOLVING Solve the equation (4x 5 16)(3x 81) = 0. Maintaining Mathematical Proficiency Reviewing what you learned in previous grades and lessons List the factor pairs of the number. (Skills Review Handbook) Chapter 7 hsnb_alg1_pe_0704.indd 382 Polynomial Equations and Factoring 2/5/15 8:13 AM

7.1 7.4 What Did You Learn? Core Vocabulary monomial, p. 358 degree of a monomial, p. 358 polynomial, p. 359 binomial, p. 359 trinomial, p. 359 degree of a polynomial, p. 359 standard form, p.

30 What Did You Learn? Core Vocabulary monomial, p. 358 degree of a monomial, p. 358 polynomial, p. 359 binomial, p. 359 trinomial, p. 359 degree of a polynomial, p. 359 standard form, p. 359 leading coefficient, p. 359 closed, p. 360 FOIL Method, p. 367 factored form, p. 378 Zero-Product Property, p. 378 roots, p. 378 repeated roots, p. 379 Core Concepts Section 7.1 Polynomials, p. 359 Adding Polynomials, p. 360 Section 7.2 Multiplying Binomials, p. 366 FOIL Method, p. 367 Subtracting Polynomials, p. 360 Multiplying Binomials and Trinomials, p. 368 Section 7.3 Square of a Binomial Pattern, p. 372 Sum and Difference Pattern, p. 373 Section 7.4 Zero-Product Property, p. 378 Factoring Polynomials Using the GCF, p. 379 Mathematical Practices 1. Explain how you wrote the polynomial in Exercise 11 on page 375. Is there another method you can use to write the same polynomial? 2. Find a shortcut for exercises like Exercise 7 on page 381 when the variable has a coefficient of 1. Does your shortcut work when the coefficient is not 1? Study Skills Preparing for a Test Review examples of each type of problem that could appear on the test. Review the homework problems your teacher assigned. Take a practice test. 383

7.1 7.4 Quiz Write the polynomial in standard form. Identify the degree and leading coefficient of the polynomial. Then classify the polynomial by the number of terms. (Section 7.1) 1. 8q3 2 3 2.

31 Quiz Write the polynomial in standard form. Identify the degree and leading coefficient of the polynomial. Then classify the polynomial by the number of terms. (Section 7.1) 1. 8q d 2 3d m4 m z + 3z z2 Find the sum or difference. (Section 7.1) 5. (2x2 + 5) + ( x2 + 4) 6. ( 3n2 + n) (2n2 7) 7. ( p2 + 4p) ( p2 3p + 15) 8. (a2 3ab + b2) + ( a2 + ab + b2) Find the product. (Section 7.2 and Section 7.3) 9. (w + 6)(w + 7) 12. (3z 5)(3z + 5) 10. (3 4d )(2d 5) 11. ( y + 9)( y2 + 2y 3) 13. (t + 5)2 14. (2q 6)2 Solve the equation. (Section 7.4) 15. 5x2 15x = (8 g)(8 g) = (3p + 7)(3p 7)( p + 8) = y( y 8)(2y + 1) = 0 x in. 19. You are making a blanket with a fringe border of equal width on each side. (Section 7.1 and Section 7.2) a. Write a polynomial that represents the perimeter of the blanket including the fringe. b. Write a polynomial that represents the area of the blanket including the fringe. c. Find the perimeter and the area of the blanket including the fringe when the width of the fringe is 4 inches. 72 in. 48 in. x in. 20. You are saving money to buy an electric guitar. You deposit $1000 in an account that earns interest compounded annually. The expression 1000(1 + r )2 represents the balance after 2 years, where r is the annual interest rate in decimal form. (Section 7.3) a. Write the polynomial in standard form that represents the balance of your account after 2 years. b. The interest rate is 3%. What is the balance of your account after 2 years? c. The guitar costs $1100. Do you have enough money in your account after 3 years? Explain. y 21. The front of a storage bunker can be modeled by 5 (x 216 y= 72)(x + 72), where x and y are measured in inches. The x-axis represents the ground. Find the width of the bunker at ground level. (Section 7.4) x Chapter 7 hsnb_alg1_pe_07mc.indd Polynomial Equations and Factoring 2/5/15 8:09 AM

32 7.5 Factoring x 2 + bx + c Essential Question How can you use algebra tiles to factor the trinomial x 2 + bx + c into the product of two binomials? Finding Binomial Factors Work with a partner. Use algebra tiles to write each polynomial as the product of two binomials. Check your answer by multiplying. Sample x 2 + 5x + 6 Step 1 Arrange algebra tiles that Step 2 Use additional algebra tiles model x 2 + 5x + 6 into a to model the dimensions of rectangular array. the rectangle. Step 3 Write the polynomial in factored form using the dimensions of the rectangle. width length Area = x 2 + 5x + 6 = (x + 2)(x + 3) a. x 2 3x + 2 = b. x 2 + 5x + 4 = c. x 2 7x + 12 = d. x 2 + 7x + 12 = REASONING ABSTRACTLY To be proficient in math, you need to understand a situation abstractly and represent it symbolically. Communicate Your Answer 2. How can you use algebra tiles to factor the trinomial x 2 + bx + c into the product of two binomials? 3. Describe a strategy for factoring the trinomial x 2 + bx + c that does not use algebra tiles. Section 7.5 Factoring x 2 + bx + c 385

33 7.5 Lesson What You Will Learn Core Vocabulary Previous polynomial FOIL Method Zero-Product Property Factor x 2 + bx + c. Use factoring to solve real-life problems. Factoring x 2 + bx + c Writing a polynomial as a product of factors is called factoring. To factor x 2 + bx + c as (x + p)(x + q), you need to find p and q such that p + q = b and pq = c. (x + p)(x + q) = x 2 + px + qx + pq Core Concept = x 2 + (p + q)x + pq Factoring x 2 + bx + c When c Is Positive Algebra x 2 + bx + c = (x + p)(x + q) when p + q = b and pq = c. When c is positive, p and q have the same sign as b. Examples x 2 + 6x + 5 = (x + 1)(x + 5) x 2 6x + 5 = (x 1)(x 5) Factor x x Factoring x 2 + bx + c When b and c Are Positive Notice that b = 10 and c = 16. Because c is positive, the factors p and q must have the same sign so that pq is positive. Because b is also positive, p and q must each be positive so that p + q is positive. Check Use the FOIL Method. (x + 2)(x + 8) = x 2 + 8x + 2x + 16 = x x + 16 Find two positive integer factors of 16 whose sum is 10. Factors of 16 Sum of factors 1, , 8 10 The values of p and q are 2 and 8. 4, 4 8 So, x x + 16 = (x + 2)(x + 8). Monitoring Progress Help in English and Spanish at BigIdeasMath.com Factor the polynomial. 1. x 2 + 7x x 2 + 9x Chapter 7 Polynomial Equations and Factoring

Factoring x 2 + bx + c When b Is Negative and c Is Positive Factor x 2 8x + 12. Notice that b = 8 and c = 12. Because c is positive, the factors p and q must have the same sign so that pq is positive.

34 Factoring x 2 + bx + c When b Is Negative and c Is Positive Factor x 2 8x Notice that b = 8 and c = 12. Because c is positive, the factors p and q must have the same sign so that pq is positive. Because b is negative, p and q must each be negative so that p + q is negative. Check Use the FOIL Method. (x 2)(x 6) = x 2 6x 2x + 12 = x 2 8x + 12 Find two negative integer factors of 12 whose sum is 8. Factors of 12 1, 12 2, 6 3, 4 Sum of factors The values of p and q are 2 and 6. So, x 2 8x + 12 = (x 2)(x 6). Core Concept Factoring x 2 + bx + c When c Is Negative Algebra x 2 + bx + c = (x + p)(x + q) when p + q = b and pq = c. When c is negative, p and q have different signs. Example x 2 4x 5 = (x + 1)(x 5) Factor x 2 + 4x 21. Factoring x 2 + bx + c When c Is Negative Check Use the FOIL Method. (x 3)(x + 7) = x 2 + 7x 3x 21 = x 2 + 4x 21 Notice that b = 4 and c = 21. Because c is negative, the factors p and q must have different signs so that pq is negative. Find two integer factors of 21 whose sum is 4. Factors of 21 21, 1 1, 21 7, 3 3, 7 Sum of factors The values of p and q are 3 and 7. So, x 2 + 4x 21 = (x 3)(x + 7). Monitoring Progress Help in English and Spanish at BigIdeasMath.com Factor the polynomial. 3. w 2 4w n 2 12n x 2 14x x 2 + 2x y y v 2 v 42 Section 7.5 Factoring x 2 + bx + c 387

35 Solving Real-Life Problems Solving a Real-Life Problem 40 m A farmer plants a rectangular pumpkin patch in the northeast corner of a square plot of land. The area of the pumpkin patch is 600 square meters. What is the area of the square plot of land? s m s m 30 m 1. Understand the Problem You are given the area of the pumpkin patch, the difference of the side length of the square plot and the length of the pumpkin patch, and the difference of the side length of the square plot and the width of the pumpkin patch. 2. Make a Plan The length of the pumpkin patch is (s 30) meters and the width is (s 40) meters. Write and solve an equation to find the side length s. Then use the solution to find the area of the square plot of land. STUDY TIP The diagram shows that the side length is more than 40 meters, so a side length of 10 meters does not make sense in this situation. The side length is 60 meters. 3. Solve the Problem Use the equation for the area of a rectangle to write and solve an equation to find the side length s of the square plot of land. 600 = (s 30)(s 40) Write an equation. 600 = s 2 70s Multiply. 0 = s 2 70s Subtract 600 from each side. 0 = (s 10)(s 60) Factor the polynomial. s 10 = 0 or s 60 = 0 Zero-Product Property s = 10 or s = 60 Solve for s. So, the area of the square plot of land is 60(60) = 3600 square meters. 4. Look Back Use the diagram to check that you found the correct side length. Using s = 60, the length of the pumpkin patch is = 30 meters and the width is = 20 meters. So, the area of the pumpkin patch is 600 square meters. This matches the given information and confirms the side length is 60 meters, which gives an area of 3600 square meters. Monitoring Progress Help in English and Spanish at BigIdeasMath.com 9. WHAT IF? The area of the pumpkin patch is 200 square meters. What is the area of the square plot of land? Concept Summary Factoring x 2 + bx + c as (x + p)(x + q) The diagram shows the relationships between the signs of b and c and the signs of p and q. x 2 + bx + c = (x + p)(x + q) c is positive. b is positive. c is positive. b is negative. c is negative. p and q are positive. p and q are negative. p and q have different signs. 388 Chapter 7 Polynomial Equations and Factoring

36 7.5 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. WRITING You are factoring x x 26. What do the signs of the terms tell you about the factors? Explain. 2. OPEN-ENDED Write a trinomial that can be factored as (x + p)(x + q), where p and q are positive. Monitoring Progress and Modeling with Mathematics In Exercises 3 8, factor the polynomial. (See Example 1.) 3. x 2 + 8x z z n 2 + 9n s s h h y y + 40 In Exercises 9 14, factor the polynomial. (See Example 2.) 26. MODELING WITH MATHEMATICS A dentist s office and parking lot are on a rectangular piece of land. The area (in square meters) of the land is represented by x 2 + x 30. (x 8) m x m 9. v 2 5v x 2 13x d 2 5d k 2 10k w 2 17w j 2 13j + 42 In Exercises 15 24, factor the polynomial. (See Example 3.) 15. x 2 + 3x z 2 + 7z n 2 + 4n s 2 + 3s y 2 + 2y h 2 + 6h x 2 x m 2 6m t 16 + t y + y MODELING WITH MATHEMATICS A projector displays an image on a wall. The area (in square feet) of the projection is represented by x 2 8x a. Write a binomial that represents the height (x 3) ft of the projection. b. Find the perimeter of x ft the projection when the height of the wall is 8 feet. (x + 6) m a. Write a binomial that represents the width of the land. b. Find the area of the land when the length of the dentist s office is 20 meters. ERROR ANALYSIS In Exercises 27 and 28, describe and correct the error in factoring the polynomial x x + 48 = (x + 4)(x + 12) s 2 17s 60 = (s 5)(s 12) In Exercises 29 38, solve the equation. 29. m 2 + 3m + 2 = n 2 9n + 18 = x 2 + 5x 14 = v v 26 = t t = n 2 5n = a 2 + 5a 20 = y 2 2y 8 = m = 15m b = 8b 10 Section 7.5 Factoring x 2 + bx + c 389

39. MODELING WITH MATHEMATICS You trimmed a large square picture so that you could fit it into a frame. The area of the cut picture is 20 square inches. What is the area of the original picture?

x in. (g 8) m 45. REASONING Write an equation of the form x 2 + bx + c = 0 that has the solutions x = 4 and x = 6. Explain how you found your answer. x in. 40.

37 39. MODELING WITH MATHEMATICS You trimmed a large square picture so that you could fit it into a frame. The area of the cut picture is 20 square inches. What is the area of the original picture? (See Example 4.) 5 in. MATHEMATICAL CONNECTIONS In Exercises 43 and 44, find the dimensions of the polygon with the given area. 43. Area = 44 ft Area = 35 m 2 (x 5) ft (x 12) ft (g 11) m 6 in. x in. (g 8) m 45. REASONING Write an equation of the form x 2 + bx + c = 0 that has the solutions x = 4 and x = 6. Explain how you found your answer. x in. 40. MODELING WITH MATHEMATICS A web browser is open on your computer screen. (x + 7) in. 46. HOW DO YOU SEE IT? The graph of y = x 2 + x 6 is shown. 8 4 y (x 2) in. x in x 8 y = x 2 + x 6 a. The area of the browser window is 24 square inches. Find the length of the browser window x. b. The browser covers 3 of the screen. What are the 13 dimensions of the screen? 41. MAKING AN ARGUMENT Your friend says there are six integer values of b for which the trinomial x 2 + bx 12 has two binomial factors of the form (x + p) and (x + q). Is your friend correct? Explain. 42. THOUGHT PROVOKING Use algebra tiles to factor each polynomial modeled by the tiles. Show your work. a. b. a. Explain how you can use the graph to factor the polynomial x 2 + x 6. b. Factor the polynomial. 47. PROBLEM SOLVING Road construction workers are paving the area shown. a. Write an expression x m that represents the area being paved. b. The area 18 m being paved is x m 280 square meters. Write and solve an equation to find 20 m the width of the road x. USING STRUCTURE In Exercises 48 51, factor the polynomial. 48. x 2 + 6xy + 8y r 2 + 7rs + 12s 2 Maintaining Mathematical Proficiency Solve the equation. Check your solution. (Section 1.1) 52. p 9 = z + 12 = = c a ab 26b x 2 2xy 35y 2 Reviewing what you learned in previous grades and lessons 55. 4k = Chapter 7 Polynomial Equations and Factoring

38 7.6 Factoring ax 2 + bx + c Essential Question How can you use algebra tiles to factor the trinomial ax 2 + bx + c into the product of two binomials? Finding Binomial Factors Work with a partner. Use algebra tiles to write each polynomial as the product of two binomials. Check your answer by multiplying. Sample 2x 2 + 5x + 2 Step 1 Arrange algebra tiles that Step 2 Use additional algebra tiles model 2x 2 + 5x + 2 into a to model the dimensions of rectangular array. the rectangle. Step 3 Write the polynomial in factored form using the dimensions of the rectangle. width length Area = 2x 2 + 5x + 2 = (x + 2)(2x + 1) a. 3x 2 + 5x + 2 = b. 4x 2 + 4x 3 = c. 2x 2 11x + 5 = USING TOOLS STRATEGICALLY To be proficient in math, you need to consider the available tools, including concrete models, when solving a mathematical problem. Communicate Your Answer 2. How can you use algebra tiles to factor the trinomial ax 2 + bx + c into the product of two binomials? 3. Is it possible to factor the trinomial 2x 2 + 2x + 1? Explain your reasoning. Section 7.6 Factoring ax 2 + bx + c 391

39 7.6 Lesson What You Will Learn Core Vocabulary Previous polynomial greatest common factor (GCF) Zero-Product Property Factor ax 2 + bx + c. Use factoring to solve real-life problems. Factoring ax 2 + bx + c In Section 7.5, you factored polynomials of the form ax 2 + bx + c, where a = 1. To factor polynomials of the form ax 2 + bx + c, where a 1, first look for the GCF of the terms of the polynomial and then factor further if possible. Factoring Out the GCF Factor 5x x Notice that the GCF of the terms 5x 2, 15x, and 10 is 5. 5x x + 10 = 5(x 2 + 3x + 2) Factor out GCF. = 5(x + 1)(x + 2) Factor x 2 + 3x + 2. So, 5x x + 10 = 5(x + 1)(x + 2). When there is no GCF, consider the possible factors of a and c. Factoring ax 2 + bx + c When ac Is Positive STUDY TIP You must consider the order of the factors of 3, because the middle terms formed by the possible factorizations are different. Factor each polynomial. a. 4x x + 3 b. 3x 2 7x + 2 a. There is no GCF, so you need to consider the possible factors of a and c. Because b and c are both positive, the factors of c must be positive. Use a table to organize information about the factors of a and c. Factors of 4 Factors of 3 Possible factorization Middle term 1, 4 1, 3 (x + 1)(4x + 3) 3x + 4x = 7x 1, 4 3, 1 (x + 3)(4x + 1) x + 12x = 13x 2, 2 1, 3 (2x + 1)(2x + 3) 6x + 2x = 8x So, 4x x + 3 = (x + 3)(4x + 1). b. There is no GCF, so you need to consider the possible factors of a and c. Because b is negative and c is positive, both factors of c must be negative. Use a table to organize information about the factors of a and c. Factors of 3 Factors of 2 Possible factorization Middle term 1, 3 1, 2 (x 1)(3x 2) 2x 3x = 5x 1, 3 2, 1 (x 2)(3x 1) x 6x = 7x So, 3x 2 7x + 2 = (x 2)(3x 1). 392 Chapter 7 Polynomial Equations and Factoring

40 Factoring ax 2 + bx + c When ac Is Negative Factor 2x 2 5x 7. There is no GCF, so you need to consider the possible factors of a and c. Because c is negative, the factors of c must have different signs. Use a table to organize information about the factors of a and c. STUDY TIP When a is negative, factor 1 from each term of ax 2 + bx + c. Then factor the resulting trinomial as in the previous examples. Factors of 2 Factors of 7 Possible factorization Middle term 1, 2 1, 7 (x + 1)(2x 7) 7x + 2x = 5x 1, 2 7, 1 (x + 7)(2x 1) x + 14x = 13x 1, 2 1, 7 (x 1)(2x + 7) 7x 2x = 5x 1, 2 7, 1 (x 7)(2x + 1) x 14x = 13x So, 2x 2 5x 7 = (x + 1)(2x 7). Factor 4x 2 8x + 5. Factoring ax 2 + bx + c When a Is Negative Step 1 Factor 1 from each term of the trinomial. 4x 2 8x + 5 = (4x 2 + 8x 5) Step 2 Factor the trinomial 4x 2 + 8x 5. Because c is negative, the factors of c must have different signs. Use a table to organize information about the factors of a and c. Factors of 4 Factors of 5 Possible factorization Middle term 1, 4 1, 5 (x + 1)(4x 5) 5x + 4x = x 1, 4 5, 1 (x + 5)(4x 1) x + 20x = 19x 1, 4 1, 5 (x 1)(4x + 5) 5x 4x = x 1, 4 5, 1 (x 5)(4x + 1) x 20x = 19x 2, 2 1, 5 (2x + 1)(2x 5) 10x + 2x = 8x 2, 2 1, 5 (2x 1)(2x + 5) 10x 2x = 8x So, 4x 2 8x + 5 = (2x 1)(2x + 5). Monitoring Progress Help in English and Spanish at BigIdeasMath.com Factor the polynomial. 1. 8x 2 56x x x x 2 7x x 2 14x x 2 19x x 2 + x y 2 5y m 2 + 6m x 2 x + 2 Section 7.6 Factoring ax 2 + bx + c 393

Solving Real-Life Problems Solving a Real-Life Problem The length of a rectangular game reserve is 1 mile longer than twice the width. The area of the reserve is 55 square miles.

41 Solving Real-Life Problems Solving a Real-Life Problem The length of a rectangular game reserve is 1 mile longer than twice the width. The area of the reserve is 55 square miles. What is the width of the reserve? Use the formula for the area of a rectangle to write an equation for the area of the reserve. Let w represent the width. Then 2w + 1 represents the length. Solve for w. w(2w + 1) = 55 Area of the reserve 2w 2 + w = 55 2w 2 + w 55 = 0 Distributive Property Subtract 55 from each side. Factor the left side of the equation. There is no GCF, so you need to consider the possible factors of a and c. Because c is negative, the factors of c must have different signs. Use a table to organize information about the factors of a and c. Factors of 2 Factors of 55 Possible factorization Middle term 1, 2 1, 55 (w + 1)(2w 55) 55w + 2w = 53w 1, 2 55, 1 (w + 55)(2w 1) w + 110w = 109w 1, 2 1, 55 (w 1)(2w + 55) 55w 2w = 53w 1, 2 55, 1 (w 55)(2w + 1) w 110w = 109w 1, 2 5, 11 (w + 5)(2w 11) 11w + 10w = w 1, 2 11, 5 (w + 11)(2w 5) 5w + 22w = 17w 1, 2 5, 11 (w 5)(2w + 11) 11w 10w = w 1, 2 11, 5 (w 11)(2w + 5) 5w 22w = 17w Check Use mental math. The width is 5 miles, so the length is 5(2) + 1 = 11 miles and the area is 5(11) = 55 square miles. So, you can rewrite 2w 2 + w 55 as (w 5)(2w + 11). Write the equation with the left side factored and continue solving for w. (w 5)(2w + 11) = 0 Rewrite equation with left side factored. w 5 = 0 or 2w + 11 = 0 w = 5 or 11 2 w = Zero-Product Property Solve for w. A negative width does not make sense, so you should use the positive solution. So, the width of the reserve is 5 miles. Monitoring Progress Help in English and Spanish at BigIdeasMath.com 10. WHAT IF? The area of the reserve is 136 square miles. How wide is the reserve? 394 Chapter 7 Polynomial Equations and Factoring

42 7.6 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. REASONING What is the greatest common factor of the terms of 3y 2 21y + 36? 2. WRITING Compare factoring 6x 2 x 2 with factoring x 2 x 2. Monitoring Progress and Modeling with Mathematics In Exercises 3 8, factor the polynomial. (See Example 1.) 3. 3x 2 + 3x v 2 + 8v k k y 2 24y b 2 63b r 2 36r 45 In Exercises 9 16, factor the polynomial. (See Examples 2 and 3.) 9. 3h h m m + 7 In Exercises 29 32, find the x-coordinates of the points where the graph crosses the x-axis y 4 x y x 11. 6x 2 5x w 2 31w + 15 y = 2x 2 3x 35 y = 4x x n 2 + 5n z 2 + 4z g 2 10g v 2 15v y y In Exercises 17 22, factor the polynomial. (See Example 4.) t t v 2 25v c c h 2 13h w 2 w d d 9 ERROR ANALYSIS In Exercises 23 and 24, describe and correct the error in factoring the polynomial x 2 2x 24 = 2(x 2 2x 24) = 2(x 6)(x + 4) 6x 2 7x 3 = (3x 3)(2x + 1) In Exercises 25 28, solve the equation. 2 2 y = 7x 2 2x + 5 x 2 4 y = 3x x MODELING WITH MATHEMATICS The area (in square feet) of the school sign can be represented by 15x 2 x 2. a. Write an expression that represents the length of the sign. b. Describe two ways to find the area of the sign when x = 3. (3x + 1) ft x 25. 5x 2 5x 30 = k 2 5k 18 = n 2 11n = b 2 2 = 3b Section 7.6 Factoring ax 2 + bx + c 395

34. MODELING WITH MATHEMATICS The height h (in feet) above the water of a cliff diver is modeled by h = 16t 2 + 8t + 80, where t is the time (in seconds). How long is the diver in the air? 35.

43 34. MODELING WITH MATHEMATICS The height h (in feet) above the water of a cliff diver is modeled by h = 16t 2 + 8t + 80, where t is the time (in seconds). How long is the diver in the air? 35. MODELING WITH MATHEMATICS The Parthenon in Athens, Greece, is an ancient structure that has a rectangular base. The length of the base of the Parthenon is 8 meters more than twice its width. The area of the base is about 2170 square meters. Find the length and width of the base. (See Example 5.) 36. MODELING WITH MATHEMATICS The length of a rectangular birthday party invitation is 1 inch less than twice its width. The area of the invitation is 15 square inches. Will the invitation fit in the envelope shown without being folded? Explain. 37. OPEN-ENDED Write a binomial whose terms have a GCF of 3x. 38. HOW DO YOU SEE IT? Without factoring, determine which of the graphs represents the function g(x) = 21x x + 12 and which represents the function h(x) = 21x 2 37x Explain your reasoning. 12 y 5 in in MAKING AN ARGUMENT Your friend says that to solve the equation 5x 2 + x 4 = 2, you should start by factoring the left side as (5x 4)(x + 1). Is your friend correct? Explain. 41. REASONING For what values of t can 2x 2 + tx + 10 be written as the product of two binomials? 42. THOUGHT PROVOKING Use algebra tiles to factor each polynomial modeled by the tiles. Show your work. a. b. 43. MATHEMATICAL CONNECTIONS The length of a rectangle is 1 inch more than twice its width. The value of the area of the rectangle (in square inches) is 5 more than the value of the perimeter of the rectangle (in inches). Find the width. 44. PROBLEM SOLVING A rectangular swimming pool is bordered by a concrete patio. The width of the patio is the same on every side. The area of the surface of the pool is equal to the area of the patio. What is the width of the patio? k 16 ft x 24 ft 39. REASONING When is it not possible to factor ax 2 + bx + c, where a 1? Give an example. 4 In Exercises 45 48, factor the polynomial k 2 + 7jk 2j x 2 + 5xy 4y a ab 14b m m 2 n 15mn 2 Maintaining Mathematical Proficiency Find the square root(s). (Skills Review Handbook) Reviewing what you learned in previous grades and lessons 49. ± ± 81 Solve the system of linear equations by substitution. Check your solution. (Section 5.2) 53. y = 3 + 7x 54. 2x = y x 2y = x 8 = y y x = 3 x + 3y = 14 7 = 2x + y 9y x = Chapter 7 Polynomial Equations and Factoring

44 7.7 Factoring Special Products Essential Question How can you recognize and factor special products? Factoring Special Products LOOKING FOR STRUCTURE To be proficient in math, you need to see complicated things as single objects or as being composed of several objects. Work with a partner. Use algebra tiles to write each polynomial as the product of two binomials. Check your answer by multiplying. State whether the product is a special product that you studied in Section 7.3. a. 4x 2 1 = b. 4x 2 4x + 1 = c. 4x 2 + 4x + 1 = d. 4x 2 6x + 2 = Factoring Special Products Work with a partner. Use algebra tiles to complete the rectangular array at the left in three different ways, so that each way represents a different special product. Write each special product in standard form and in factored form. Communicate Your Answer 3. How can you recognize and factor special products? Describe a strategy for recognizing which polynomials can be factored as special products. 4. Use the strategy you described in Question 3 to factor each polynomial. a. 25x x + 1 b. 25x 2 10x + 1 c. 25x 2 1 Section 7.7 Factoring Special Products 397

45 7.7 Lesson What You Will Learn Core Vocabulary Previous polynomial trinomial Factor the difference of two squares. Factor perfect square trinomials. Use factoring to solve real-life problems. Factoring the Difference of Two Squares You can use special product patterns to factor polynomials. Core Concept Difference of Two Squares Pattern Algebra Example a 2 b 2 = (a + b)(a b) x 2 9 = x = (x + 3)(x 3) Factoring the Difference of Two Squares Factor (a) x 2 25 and (b) 4z 2 1. a. x 2 25 = x Write as a 2 b 2. = (x + 5)(x 5) Difference of two squares pattern So, x 2 25 = (x + 5)(x 5). b. 4z 2 1 = (2z) Write as a 2 b 2. = (2z + 1)(2z 1) Difference of two squares pattern So, 4z 2 1 = (2z + 1)(2z 1). Evaluating a Numerical Expression Use a special product pattern to evaluate the expression Notice that is a difference of two squares. So, you can rewrite the expression in a form that it is easier to evaluate using the difference of two squares pattern = ( )(54 48) Difference of two squares pattern So, = 612. = 102(6) Simplify. = 612 Multiply. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Factor the polynomial. 1. x m n h 2 49 Use a special product pattern to evaluate the expression Chapter 7 Polynomial Equations and Factoring

46 Factoring Perfect Square Trinomials Core Concept Perfect Square Trinomial Pattern Algebra Example a 2 + 2ab + b 2 = (a + b) 2 x 2 + 6x + 9 = x 2 + 2(x)(3) = (x + 3) 2 a 2 2ab + b 2 = (a b) 2 x 2 6x + 9 = x 2 2(x)(3) = (x 3) 2 Factoring Perfect Square Trinomials Factor each polynomial. a. n 2 + 8n + 16 b. 4x 2 12x + 9 a. n 2 + 8n + 16 = n 2 + 2(n)(4) Write as a 2 + 2ab + b 2. = (n + 4) 2 Perfect square trinomial pattern So, n 2 + 8n + 16 = (n + 4) 2. b. 4x 2 12x + 9 = (2x) 2 2(2x)(3) Write as a 2 2ab + b 2. = (2x 3) 2 Perfect square trinomial pattern So, 4x 2 12x + 9 = (2x 3) 2. Solving a Polynomial Equation LOOKING FOR STRUCTURE Equations of the form (x + a) 2 = 0 always have repeated roots of x = a. Solve x x = 0. x x + 1 = 0 Write equation. 9 9x 2 + 6x + 1 = 0 Multiply each side by 9. (3x) 2 + 2(3x)(1) = 0 Write left side as a 2 + 2ab + b 2. (3x + 1) 2 = 0 Perfect square trinomial pattern 3x + 1 = 0 The solution is x = 1 3 x = 1 3. Monitoring Progress Factor the polynomial. Zero-Product Property Solve for x. Help in English and Spanish at BigIdeasMath.com 9. m 2 2m d 2 10d z z + 36 Solve the equation. 12. a 2 + 6a + 9 = w w = n2 81 = 0 Section 7.7 Factoring Special Products 399

Understand the Problem You are given the y = 81 16t height of the golf ball as a function of the amount 2 of time after it is dropped and the height of the tree that the golf ball hits.

47 Solving Real-Life Problems Modeling with Mathematics A bird picks up a golf ball and drops it while flying. The function represents the height y (in feet) of the golf ball t seconds after it is dropped. The ball hits the top of a 32-foot-tall pine tree. After how many seconds does the ball hit the tree? 1. Understand the Problem You are given the y = 81 16t height of the golf ball as a function of the amount 2 of time after it is dropped and the height of the tree that the golf ball hits. You are asked to determine how many seconds it takes for the ball to hit the tree. 2. Make a Plan Use the function for the height of the golf ball. Substitute the height of the tree for y and solve for the time t. 3. Solve the Problem Substitute 32 for y and solve for t. y = 81 16t 2 Write equation. 32 = 81 16t 2 Substitute 32 for y. 0 = 49 16t 2 Subtract 32 from each side. 0 = 7 2 (4t) 2 Write as a 2 b 2. 0 = (7 + 4t)(7 4t) Difference of two squares pattern 7 + 4t = 0 or 7 4t = 0 Zero-Product Property 7 t = 4 or t = 7 4 Solve for t. A negative time does not make sense in this situation. So, the golf ball hits the tree after 7, or 1.75 seconds Look Back Check your solution, as shown, by substituting t = 7 into the equation 4 32 = 81 16t 2. Then verify that a time of 7 seconds gives a height of 32 feet. 4 Check 32 = 81 16t 2 32 =? ( 7 4 ) 2 32 =? ( =? = ) Monitoring Progress Help in English and Spanish at BigIdeasMath.com 15. WHAT IF? The golf ball does not hit the pine tree. After how many seconds does the ball hit the ground? 400 Chapter 7 Polynomial Equations and Factoring

7.7 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. REASONING Can you use the perfect square trinomial pattern to factor y 2 + 16y + 64? Explain. 2. WHICH ONE DOESN T BELONG?

48 7.7 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. REASONING Can you use the perfect square trinomial pattern to factor y y + 64? Explain. 2. WHICH ONE DOESN T BELONG? Which polynomial does not belong with the other three? Explain your reasoning. n 2 4 g 2 6g + 9 r r + 36 k Monitoring Progress and Modeling with Mathematics In Exercises 3 8, factor the polynomial. (See Example 1.) 3. m z d x a 2 36b x 2 169y 2 In Exercises 9 14, use a special product pattern to evaluate the expression. (See Example 2.) In Exercises 15 22, factor the polynomial. (See Example 3.) 15. h h p p y 2 22y x 2 4x a 2 28a m m n n a 2 14a + 1 ERROR ANALYSIS In Exercises 23 and 24, describe and correct the error in factoring the polynomial n 2 64 = n = (n 8) 2 y 2 6y + 9 = y 2 2(y)(3) = (y 3) (y + 3) 25. MODELING WITH MATHEMATICS The area (in square centimeters) of a square coaster can be represented by d 2 + 8d a. Write an expression that represents the side length of the coaster. b. Write an expression for the perimeter of the coaster. 26. MODELING WITH MATHEMATICS The polynomial represents the area (in square feet) of the square playground. a. Write a polynomial that represents the side length of the playground. A = x 2 30x b. Write an expression for the perimeter of the playground. In Exercises 27 34, solve the equation. (See Example 4.) 27. z 2 4 = x 2 = k 2 16k + 64 = s s = n = 6n 32. y 2 = 12y y y = x = x2 In Exercises 35 40, factor the polynomial z m y 2 16y k k y y m 2 36m + 12 Section 7.7 Factoring Special Products 401

49 41. MODELING WITH MATHEMATICS While standing on a ladder, you drop a paintbrush. The function represents the height y (in feet) of the paintbrush t seconds after it is dropped. After how many seconds does the paintbrush land on the ground? (See Example 5.) 46. HOW DO YOU SEE IT? The figure shows a large square with an area of a 2 that contains a smaller square with an area of b 2. a a y = 25 16t MODELING WITH MATHEMATICS The function represents the height y (in feet) of a grasshopper jumping straight up from the ground t seconds after the start of the jump. After how many seconds is the grasshopper 1 foot off the ground? 43. REASONING Tell whether the polynomial can be factored. If not, change the constant term so that the polynomial is a perfect square trinomial. a. w w + 84 b. y 2 10y THOUGHT PROVOKING Use algebra tiles to factor each polynomial modeled by the tiles. Show your work. a. b. y = 16t 2 + 8t 45. COMPARING METHODS Describe two methods you can use to simplify (2x 5) 2 (x 4) 2. Which one would you use? Explain. Maintaining Mathematical Proficiency Write the prime factorization of the number. (Skills Review Handbook) b b a. Describe the regions that represent a 2 b 2. How can you rearrange these regions to show that a 2 b 2 = (a + b)(a b)? b. How can you use the figure to show that (a b) 2 = a 2 2ab + b 2? 47. PROBLEM SOLVING You hang nine identical square picture frames on a wall. a. Write a polynomial that represents the area of the picture frames, not including the pictures. b. The area in part (a) 4 in. is 81 square inches. x in. 4 in. What is the side x in. length of one of the picture frames? Explain your reasoning. 48. MATHEMATICAL CONNECTIONS The composite solid is made up of a cube and a rectangular prism. a. Write a polynomial that represents the 4 in. volume of the composite solid. x in. x in. b. The volume of the composite solid is equal to 25x. What is the value x in. 4 in. of x? Explain your reasoning Graph the inequality in a coordinate plane. (Section 5.6) y 4x y > x y 12 8x 56. 3y + 3 < x 2 Reviewing what you learned in previous grades and lessons 402 Chapter 7 Polynomial Equations and Factoring

50 REASONING ABSTRACTLY 7.8 To be proficient in math, you need to know and flexibly use different properties of operations and objects. Factoring Polynomials Completely Essential Question How can you factor a polynomial completely? Writing a Product of Linear Factors Work with a partner. Write the product represented by the algebra tiles. Then multiply to write the polynomial in standard form. a. ( )( )( ) b. ( )( )( ) c. ( )( )( ) d. ( )( )( ) e. ( )( )( ) f. ( )( )( ) Matching Standard and Factored Forms Work with a partner. Match the standard form of the polynomial with the equivalent factored form. Explain your strategy. a. x 3 + x 2 A. x(x + 1)(x 1) b. x 3 x B. x(x 1) 2 c. x 3 + x 2 2x C. x(x + 1) 2 d. x 3 4x 2 + 4x D. x(x + 2)(x 1) e. x 3 2x 2 3x E. x(x 1)(x 2) f. x 3 2x 2 + x F. x(x + 2)(x 2) g. x 3 4x G. x(x 2) 2 h. x 3 + 2x 2 H. x(x + 2) 2 i. x 3 x 2 I. x 2 (x 1) j. x 3 3x 2 + 2x J. x 2 (x + 1) k. x 3 + 2x 2 3x K. x 2 (x 2) l. x 3 4x 2 + 3x L. x 2 (x + 2) m. x 3 2x 2 M. x(x + 3)(x 1) n. x 3 + 4x 2 + 4x N. x(x + 1)(x 3) o. x 3 + 2x 2 + x O. x(x 1)(x 3) Communicate Your Answer 3. How can you factor a polynomial completely? 4. Use your answer to Question 3 to factor each polynomial completely. a. x 3 + 4x 2 + 3x b. x 3 6x 2 + 9x c. x 3 + 6x 2 + 9x Section 7.8 Factoring Polynomials Completely 403

51 7.8 Lesson What You Will Learn Core Vocabulary factoring by grouping, p. 404 factored completely, p. 404 Previous polynomial binomial Factor polynomials by grouping. Factor polynomials completely. Use factoring to solve real-life problems. Factoring Polynomials by Grouping You have used the Distributive Property to factor out a greatest common monomial from a polynomial. Sometimes, you can factor out a common binomial. You may be able to use the Distributive Property to factor polynomials with four terms, as described below. Core Concept Factoring by Grouping To factor a polynomial with four terms, group the terms into pairs. Factor the GCF out of each pair of terms. Look for and factor out the common binomial factor. This process is called factoring by grouping. Factoring by Grouping Factor each polynomial by grouping. a. x 3 + 3x 2 + 2x + 6 b. x 2 + y + x + xy a. x 3 + 3x 2 + 2x + 6 = (x 3 + 3x 2 ) + (2x + 6) Group terms with common factors. Common binomial factor is x + 3. = x 2 (x + 3) + 2(x + 3) Factor out GCF of each pair of terms. = (x + 3)(x 2 + 2) Factor out (x + 3). So, x 3 + 3x 2 + 2x + 6 = (x + 3)(x 2 + 2). b. x 2 + y + x + xy = x 2 + x + xy + y Rewrite polynomial. = (x 2 + x) + (xy + y) Group terms with common factors. Common binomial factor is x + 1. = x(x + 1) + y(x + 1) Factor out GCF of each pair of terms. = (x + 1)(x + y) Factor out (x + 1). So, x 2 + y + x + xy = (x + 1)(x + y). Monitoring Progress Help in English and Spanish at BigIdeasMath.com Factor the polynomial by grouping. 1. a 3 + 3a 2 + a y 2 + 2x + yx + 2y Factoring Polynomials Completely You have seen that the polynomial x 2 1 can be factored as (x + 1)(x 1). This polynomial is factorable. Notice that the polynomial x cannot be written as the product of polynomials with integer coefficients. This polynomial is unfactorable. A factorable polynomial with integer coefficients is factored completely when it is written as a product of unfactorable polynomials with integer coefficients. 404 Chapter 7 Polynomial Equations and Factoring

52 Concept Summary Guidelines for Factoring Polynomials Completely To factor a polynomial completely, you should try each of these steps. 1. Factor out the greatest common monomial factor. 3x 2 + 6x = 3x(x + 2) 2. Look for a difference of two squares or a perfect x 2 + 4x + 4 = (x + 2) 2 square trinomial. 3. Factor a trinomial of the form ax 2 + bx + c into a product 3x 2 5x 2 = (3x + 1)(x 2) of binomial factors. 4. Factor a polynomial with four terms by grouping. x 3 + x 4x 2 4 = (x 2 + 1)(x 4) Factoring Completely Factor (a) 3x 3 + 6x 2 18x and (b) 7x 4 28x 2. a. 3x 3 + 6x 2 18x = 3x(x 2 + 2x 6) Factor out 3x. x 2 + 2x 6 is unfactorable, so the polynomial is factored completely. So, 3x 3 + 6x 2 18x = 3x(x 2 + 2x 6). b. 7x 4 28x 2 = 7x 2 (x 2 4) Factor out 7x 2. = 7x 2 (x ) Write as a 2 b 2. = 7x 2 (x + 2)(x 2) Difference of two squares pattern So, 7x 4 28x 2 = 7x 2 (x + 2)(x 2). Solve 2x 3 + 8x 2 = 10x. Solving an Equation by Factoring Completely 2x 3 + 8x 2 = 10x 2x 3 + 8x 2 10x = 0 Original equation Subtract 10x from each side. 2x(x 2 + 4x 5) = 0 Factor out 2x. 2x(x + 5)(x 1) = 0 Factor x 2 + 4x 5. 2x = 0 or x + 5 = 0 or x 1 = 0 Zero-Product Property x = 0 or x = 5 or x = 1 Solve for x. The roots are x = 5, x = 0, and x = 1. Monitoring Progress Help in English and Spanish at BigIdeasMath.com Factor the polynomial completely. 3. 3x 3 12x 4. 2y 3 12y y 5. m 3 2m 2 8m Solve the equation. 6. w 3 8w w = 0 7. x 3 25x = 0 8. c 3 7c c = 0 Section 7.8 Factoring Polynomials Completely 405

(36 w) in. Check V = wh Solving Real-Life Problems Modeling with Mathematics A terrarium in the shape of a rectangular prism has a volume of 4608 cubic inches. Its length is more than 10 inches.

53 (36 w) in. Check V = wh Solving Real-Life Problems Modeling with Mathematics A terrarium in the shape of a rectangular prism has a volume of 4608 cubic inches. Its length is more than 10 inches. The dimensions of the terrarium in terms of its width are shown. Find the length, width, and height of the terrarium. (w + 4) in. w in =? 24(12)(16) 4608 = Understand the Problem You are given the volume of a terrarium in the shape of a rectangular prism and a description of the length. The dimensions are written in terms of its width. You are asked to find the length, width, and height of the terrarium. 2. Make a Plan Use the formula for the volume of a rectangular prism to write and solve an equation for the width of the terrarium. Then substitute that value in the expressions for the length and height of the terrarium. 3. Solve the Problem Volume = length width height Volume of a rectangular prism 4608 = (36 w)(w)(w + 4) Write equation = 32w w w 3 Multiply. 0 = 32w w w Subtract 4608 from each side. 0 = ( w w 2 ) + (144w 4608) Group terms with common factors. 0 = w 2 (w 32) + 144(w 32) Factor out GCF of each pair of terms. 0 = (w 32)( w ) Factor out (w 32). 0 = 1(w 32)(w 2 144) Factor 1 from w = 1(w 32)(w 12)(w + 12) Difference of two squares pattern w 32 = 0 or w 12 = 0 or w + 12 = 0 Zero-Product Property w = 32 or w = 12 or w = 12 Solve for w. Disregard w = 12 because a negative width does not make sense. You know that the length is more than 10 inches. Test the solutions of the equation, 12 and 32, in the expression for the length. length = 36 w = = 24 or length = 36 w = = 4 The solution 12 gives a length of 24 inches, so 12 is the correct value of w. Use w = 12 to find the height, as shown. height = w + 4 = = 16 The width is 12 inches, the length is 24 inches, and the height is 16 inches. 4. Look Back Check your solution. Substitute the values for the length, width, and height when the width is 12 inches into the formula for volume. The volume of the terrarium should be 4608 cubic inches. Monitoring Progress Help in English and Spanish at BigIdeasMath.com 9. A box in the shape of a rectangular prism has a volume of 72 cubic feet. The box has a length of x feet, a width of (x 1) feet, and a height of (x + 9) feet. Find the dimensions of the box. 406 Chapter 7 Polynomial Equations and Factoring

7.8 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. VOCABULARY What does it mean for a polynomial to be factored completely? 2.

54 7.8 Exercises Dynamic Solutions available at BigIdeasMath.com Vocabulary and Core Concept Check 1. VOCABULARY What does it mean for a polynomial to be factored completely? 2. WRITING Explain how to choose which terms to group together when factoring by grouping. Monitoring Progress and Modeling with Mathematics In Exercises 3 10, factor the polynomial by grouping. (See Example 1.) 3. x 3 + x 2 + 2x y 3 9y 2 + y y x 420 y 5. 3z 3 + 2z 12z s s + 3s 2 7. x 2 + xy + 8x + 8y 8. q 2 + q + 5pq + 5p 9. m 2 3m + mn 3n 10. 2a 2 + 8ab 3a 12b y = 2x x 3 32x x 140 y = 4x x 2 56x In Exercises 11 22, factor the polynomial completely. (See Example 2.) 11. 2x 3 2x a 4 4a c 2 7c m 2 5m g 3 24g g d d 2 6d 17. 3r 5 + 3r 4 90r w 4 40w w c 4 + 8c 3 28c t 2 + 8t b 3 5b 2 4b h 3 + 4h 2 25h 100 ERROR ANALYSIS In Exercises 33 and 34, describe and correct the error in factoring the polynomial completely a 3 + 8a 2 6a 48 = a 2 (a + 8) + 6(a + 8) = (a + 8)(a 2 + 6) x 3 6x 2 9x + 54 = x 2 (x 6) 9(x 6) = (x 6)(x 2 9) In Exercises 23 28, solve the equation. (See Example 3.) 23. 5n 3 30n n = k 4 100k 2 = x 3 + x 2 = 4x t 5 + 2t 4 144t 3 = s 3s 3 = y 3 7y = 16y In Exercises 29 32, find the x-coordinates of the points where the graph crosses the x-axis. 29. y y 35. MODELING WITH MATHEMATICS You are building a birdhouse in the shape of a rectangular prism that has a volume of 128 cubic inches. The dimensions of the birdhouse in terms of (w + 4) in. its width are shown. (See Example 4.) a. Write a polynomial that represents the volume of the birdhouse. w in. 4 in x x b. What are the dimensions of the birdhouse? y = x 3 81x y = 3x 4 24x 3 45x 2 Section 7.8 Factoring Polynomials Completely 407

55 36. MODELING WITH MATHEMATICS A gift bag shaped like a rectangular prism has a volume of 1152 cubic inches. The dimensions of the gift bag in terms of its width are shown. The height is greater than the width. What are the dimensions of the gift bag? (2w + 4) in. (18 w) in. w in. In Exercises 37 40, factor the polynomial completely. 37. x 3 + 2x 2 y x 2y 38. 8b 3 4b 2 a 18b + 9a 39. 4s 2 s + 12st 3t 40. 6m 3 12mn + m 2 n 2n WRITING Is it possible to find three real solutions of the equation x 3 + 2x 2 + 3x + 6 = 0? Explain your reasoning. 42. HOW DO YOU SEE IT? How can you use the factored form of the polynomial x 4 2x 3 9x x = x(x 3)(x + 3)(x 2) to find the x-intercepts of the graph of the function? 44. MAKING AN ARGUMENT Your friend says that if a trinomial cannot be factored as the product of two binomials, then the trinomial is factored completely. Is your friend correct? Explain. 45. PROBLEM SOLVING The volume (in cubic feet) of a room in the shape of a rectangular prism is represented by 12z 3 27z. Find expressions that could represent the dimensions of the room. 46. MATHEMATICAL CONNECTIONS The width of a box in the shape of a rectangular prism is 4 inches more than the height h. The length is the difference of 9 inches and the height. a. Write a polynomial that represents the volume of the box in terms of its height (in inches). b. The volume of the box is 180 cubic inches. What are the possible dimensions of the box? c. Which dimensions result in a box with the least possible surface area? Explain your reasoning. 47. MATHEMATICAL CONNECTIONS The volume of a cylinder is given by V = πr 2 h, where r is the radius of the base of the cylinder and h is the height of the cylinder. Find the dimensions of the cylinder. 20 y Volume = 25hπ h 2 2 x h 3 40 y = x 4 2x 3 9x x 48. THOUGHT PROVOKING Factor the polynomial x 5 x 4 5x 3 + 5x 2 + 4x 4 completely. 43. OPEN-ENDED Write a polynomial of degree 3 that satisfies each of the given conditions. a. is not factorable b. can be factored by grouping 49. REASONING Find a value for w so that the equation has (a) two solutions and (b) three solutions. Explain your reasoning. 5x 3 + wx x = 0 Maintaining Mathematical Proficiency Solve the system of linear equations by graphing. (Section 5.1) 50. y = x y = 1 x x y = x = 3y 2 1 y = 2x + 2 y = 3x 3 x + y = 9 y 10 = 2x Graph the function. Describe the domain and range. (Section 6.3) 54. f(x) = 5 x 55. y = 9 ( 1 3 ) x 56. y = 3(0.5) x 57. f(x) = 3(4) x 4 Reviewing what you learned in previous grades and lessons 408 Chapter 7 Polynomial Equations and Factoring

7.5 7.8 What Did You Learn? Core Vocabulary factoring by grouping, p. 404 factored completely, p. 404 Core Concepts Section 7.5 Factoring x 2 + bx + c When c Is Positive, p.

56 What Did You Learn? Core Vocabulary factoring by grouping, p. 404 factored completely, p. 404 Core Concepts Section 7.5 Factoring x 2 + bx + c When c Is Positive, p. 386 Factoring x 2 + bx + c When c Is Negative, p. 387 Section 7.6 Factoring ax 2 + bx + c When ac Is Positive, p. 392 Factoring ax 2 + bx + c When ac Is Negative, p. 393 Section 7.7 Difference of Two Squares Pattern, p. 398 Perfect Square Trinomial Pattern, p. 399 Section 7.8 Factoring by Grouping, p. 404 Factoring Polynomials Completely, p. 404 Mathematical Practices 1. How are the solutions of Exercise 29 on page 389 related to the graph of y = m 2 + 3m + 2? 2. The equation in part (b) of Exercise 47 on page 390 has two solutions. Are both solutions of the equation reasonable in the context of the problem? Explain your reasoning. The way an equation or expression is written can help you interpret and solve problems. Which representation would you rather have when trying to solve for specific information? Why? To explore the answers to these questions and more, go to BigIdeasMath.com. Performance Task The View Matters 409

57 7 Chapter Review Dynamic Solutions available at BigIdeasMath.com 7.1 Adding and Subtracting Polynomials (pp ) Find (2x 3 + 6x 2 x) ( 3x 3 2x 2 9x). (2x 3 + 6x 2 x) ( 3x 3 2x 2 9x) = (2x 3 + 6x 2 x) + (3x 3 + 2x 2 + 9x) = (2x 3 + 3x 3 ) + (6x 2 + 2x 2 ) + ( x + 9x) = 5x 3 + 8x 2 + 8x Write the polynomial in standard form. Identify the degree and leading coefficient of the polynomial. Then classify the polynomial by the number of terms x p 3 + 5p x 7 6x x y + 8y 3 Find the sum or difference. 5. (3a + 7) + (a 1) 6. (x 2 + 6x 5) + (2x ) 7. ( y 2 + y + 2) (y 2 5y 2) 8. (p + 7) (6p p) 7.2 Multiplying Polynomials (pp ) Find (x + 7)(x 9). (x + 7)(x 9) = x(x 9) + 7(x 9) Distribute (x 9) to each term of (x + 7). = x(x) + x( 9) + 7(x) + 7( 9) Distributive Property = x 2 + ( 9x) + 7x + ( 63) Multiply. = x 2 2x 63 Combine like terms. Find the product. 9. (x + 6)(x 4) 10. (y 5)(3y + 8) 11. (x + 4)(x 2 + 7x) 12. ( 3y + 1)(4y 2 y 7) 7.3 Special Products of Polynomials (pp ) Find each product. a. (6x + 4y) 2 (6x + 4y) 2 = (6x) 2 + 2(6x)(4y) + (4y) 2 Square of a binomial pattern = 36x xy + 16y 2 Simplify. b. (2x + 3y)(2x 3y) (2x + 3y)(2x 3y) = (2x) 2 (3y) 2 Sum and difference pattern = 4x 2 9y 2 Simplify. Find the product. 13. (x + 9)(x 9) 14. (2y + 4)(2y 4) 15. ( p + 4) ( 1 + 2d ) Chapter 7 Polynomial Equations and Factoring

58 7.4 Solving Polynomial Equations in Factored Form (pp ) Solve (x + 6)(x 8) = 0. (x + 6)(x 8) = 0 Write equation. x + 6 = 0 or x 8 = 0 Zero-Product Property x = 6 or x = 8 Solve for x. Solve the equation. 17. x 2 + 5x = (z + 3)(z 7) = (b + 13) 2 = y(y 9)(y + 4) = Factoring x 2 + bx + c (pp ) Factor x 2 + 6x 27. Notice that b = 6 and c = 27. Because c is negative, the factors p and q must have different signs so that pq is negative. Find two integer factors of 27 whose sum is 6. Factors of 27 27, 1 1, 27 9, 3 3, 9 Sum of factors The values of p and q are 3 and 9. So, x 2 + 6x 27 = (x 3)(x + 9). Factor the polynomial. 21. p 2 + 2p b b z 2 4z x 2 11x Factoring ax 2 + bx + c (pp ) Factor 5x x + 7. There is no GCF, so you need to consider the possible factors of a and c. Because b and c are both positive, the factors of c must be positive. Use a table to organize information about the factors of a and c. Factors of 5 Factors of 7 Possible factorization Middle term 1, 5 1, 7 (x + 1)(5x + 7) 7x + 5x = 12x 1, 5 7, 1 (x + 7)(5x + 1) x + 35x = 36x So, 5x x + 7 = (x + 7)(5x + 1). Factor the polynomial t t y 2 22y x x y 2 + 7y z z a 2 13a 3 Chapter 7 Chapter Review 411

59 7.7 Factoring Special Products (pp ) Factor each polynomial. a. x 2 16 x 2 16 = x Write as a 2 b 2. = (x + 4)(x 4) Difference of two squares pattern b. 25x 2 30x x 2 30x + 9 = (5x) 2 2(5x)(3) Write as a 2 2ab + b 2. = (5x 3) 2 Perfect square trinomial pattern Factor the polynomial. 31. x y z 2 6z m m Factoring Polynomials Completely (pp ) Factor each polynomial completely. a. x 3 + 4x 2 3x 12 x 3 + 4x 2 3x 12 = (x 3 + 4x 2 ) + ( 3x 12) b. 2x 4 8x 2 Group terms with common factors. = x 2 (x + 4) + ( 3)(x + 4) Factor out GCF of each pair of terms. = (x + 4)(x 2 3) Factor out (x + 4). 2x 4 8x 2 = 2x 2 (x 2 4) Factor out 2x 2. = 2x 2 (x ) Write as a 2 b 2. = 2x 2 (x + 2)(x 2) Difference of two squares pattern c. 2x x 2 72x 2x x 2 72x = 2x(x 2 + 9x 36) Factor out 2x. Factor the polynomial completely. = 2x(x + 12)(x 3) Factor x 2 + 9x n 3 9n 36. x 2 3x + 4ax 12a 37. 2x 4 + 2x 3 20x 2 Solve the equation x 3 9x 2 54x = x 2 36 = z 3 + 3z 2 25z 75 = A box in the shape of a rectangular prism has a volume of 96 cubic feet. The box has a length of (x + 8) feet, a width of x feet, and a height of (x 2) feet. Find the dimensions of the box. 412 Chapter 7 Polynomial Equations and Factoring

7 Chapter Test Find the sum or difference. Then identify the degree of the sum or difference and classify it by the number of terms. 1. ( 2p + 4) (p 2 6p + 8) 2. (9c 6 5b 4 ) (4c 6 5b 4 ) 3.

60 7 Chapter Test Find the sum or difference. Then identify the degree of the sum or difference and classify it by the number of terms. 1. ( 2p + 4) (p 2 6p + 8) 2. (9c 6 5b 4 ) (4c 6 5b 4 ) 3. (4s 4 + 2st + t) + (2s 4 2st 4t) Find the product. 4. (h 5)(h 8) 5. (2w 3)(3w + 5) 6. (z + 11)(z 11) 7. Explain how you can determine whether a polynomial is a perfect square trinomial. 8. Is 18 a polynomial? Explain your reasoning. Factor the polynomial completely. 9. s 2 15s h 3 + 2h 2 9h k 2 22k + 15 Solve the equation. 12. (n 1)(n + 6)(n + 5) = d d + 49 = x 4 + 8x 2 = 26x The expression π(r 3) 2 represents the area covered by the hour hand on a clock in one rotation, where r is the radius of the entire clock. Write a polynomial in standard form that represents the area covered by the hour hand in one rotation. 16. A magician s stage has a trapdoor. a. The total area (in square feet) of the stage can be represented by x x Write an expression for the width of the stage. b. Write an expression for the perimeter of the stage. c. The area of the trapdoor is 10 square feet. Find the value of x. d. The magician wishes to have the area of the stage be at least 20 times the area of the trapdoor. Does this stage satisfy his requirement? Explain. 2x ft (x + 16) ft 1 (x + ) ft Write a polynomial equation in factored form that has three positive roots. 18. You are jumping on a trampoline. For one jump, your height y (in feet) above the trampoline after t seconds can be represented by y = 16t t. How many seconds are you in the air? 19. A cardboard box in the shape of a rectangular prism has the dimensions shown. a. Write a polynomial that represents the volume of the box. b. The volume of the box is 60 cubic inches. What are the length, width, and height of the box? (x + 6) in. (x 1) in. (x 2) in. Chapter 7 Chapter Test 413

= The algebraic expression is 3x 2 x The algebraic expression is x 2 + x. 3. The algebraic expression is x 2 2x.

= The algebraic expression is 3x 2 x The algebraic expression is x 2 + x. 3. The algebraic expression is x 2 2x. Chapter 7 Maintaining Mathematical Proficiency (p. 335) 1. 3x 7 x = 3x x 7 = (3 )x 7 = 5x 7. 4r 6 9r 1 = 4r 9r 6 1 = (4 9)r 6 1 = 5r 5 3. 5t 3 t 4 8t = 5t t 8t 3 4 = ( 5 1 8)t 3 4 = ()t ( 1) = t 1 4. 3(s